SuperHyperMatching By (R-)Definitions And Polynomials To Monitor Cancer's Recognition In Neutrosophic SuperHyperGraphs
Description
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\textbf\newline{
SuperHyperMatching By (R-)Definitions And Polynomials
To Monitor Cancer's Recognition In Neutrosophic SuperHyperGraphs
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% authors go here:
Henry Garrett
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DrHenryGarrett@gmail.com
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Twitter's ID: @DrHenryGarrett $|$ \copyright DrHenryGarrett.wordpress.com
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\section*{ABSTRACT}
In this research, new setting is introduced for new SuperHyperNotions, namely, a SuperHyperMatching and Neutrosophic SuperHyperMatching . Two different types of SuperHyperDefinitions are debut for them but the research goes further and the SuperHyperNotion, SuperHyperUniform, and SuperHyperClass based on that are well-defined and well-reviewed. The literature review is implemented in the whole of this research. For shining the elegancy and the significancy of this research, the comparison between this SuperHyperNotion with other SuperHyperNotions and fundamental SuperHyperNumbers are featured. The definitions are followed by the examples and the instances thus the clarifications are driven with different tools. The applications are figured out to make sense about the theoretical aspect of this ongoing research. The ``Cancer's Recognition'' are the under research to figure out the challenges make sense about ongoing and upcoming research. The special case is up. The cells are viewed in the deemed ways. There are different types of them. Some of them are individuals and some of them are well-modeled by the group of cells. These types are all officially called ``SuperHyperVertex'' but the relations amid them all officially called ``SuperHyperEdge''. The frameworks ``SuperHyperGraph'' and ``neutrosophic SuperHyperGraph'' are chosen and elected to research about ``Cancer's Recognition''. Thus these complex and dense SuperHyperModels open up some avenues to research on theoretical segments and ``Cancer's Recognition''. Some avenues are posed to pursue this research. It's also officially collected in the form of some questions and some problems. Assume a SuperHyperGraph. Then a neutrosophic SuperHyperMatching $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the maximum cardinality of a SuperHyperSet $S$ of high cardinality SuperHyperEdges such that there's no SuperHyperVertex not to in a SuperHyperEdge and there's no SuperHyperEdge to have a SuperHyperVertex in a SuperHyperEdge; a neutrosophic SuperHyperMatching $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of high neutrosophic cardinality neutrosophic SuperHyperEdges such that there's no neutrosophic SuperHyperVertex not to in a neutrosophic SuperHyperEdge and there's no neutrosophic SuperHyperEdge to have a neutrosophic SuperHyperVertex in a neutrosophic SuperHyperEdge; a neutrosophic SuperHyperMatching SuperHyperPolynomial $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the neutrosophic SuperHyperPolynomial contains the coefficients defined as the number of the maximum cardinality of a SuperHyperSet $S$ of high cardinality SuperHyperEdges such that there's no SuperHyperVertex not to in a SuperHyperEdge and there's no SuperHyperEdge to have a SuperHyperVertex in a SuperHyperEdge and the power is corresponded to its coefficient; a neutrosophic SuperHyperMatching SuperHyperPolynomial $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the neutrosophic SuperHyperPolynomial contains the neutrosophic coefficients defined as the neutrosophic number of the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of high neutrosophic cardinality neutrosophic SuperHyperEdges such that there's no neutrosophic SuperHyperVertex not to in a neutrosophic SuperHyperEdge and there's no neutrosophic SuperHyperEdge to have a neutrosophic SuperHyperVertex in a neutrosophic SuperHyperEdge and the neutrosophic power is neutrosophicly corresponded to its neutrosophic coefficient; a neutrosophic R-SuperHyperMatching $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the maximum cardinality of a SuperHyperSet $S$ of high cardinality SuperHyperVertices such that there's no SuperHyperVertex not to in a SuperHyperEdge and there's no SuperHyperEdge to have a SuperHyperVertex in a SuperHyperEdge; a neutrosophic R-SuperHyperMatching $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of high neutrosophic cardinality neutrosophic SuperHyperVertices such that there's no neutrosophic SuperHyperVertex not to in a neutrosophic SuperHyperEdge and there's no neutrosophic SuperHyperEdge to have a neutrosophic SuperHyperVertex in a neutrosophic SuperHyperEdge; a neutrosophic R-SuperHyperMatching SuperHyperPolynomial $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the neutrosophic SuperHyperPolynomial contains the coefficients defined as the number of the maximum cardinality of a SuperHyperSet $S$ of high cardinality SuperHyperVertices such that there's no SuperHyperVertex not to in a SuperHyperEdge and there's no SuperHyperEdge to have a SuperHyperVertex in a SuperHyperEdge and the power is corresponded to its coefficient; a neutrosophic R-SuperHyperMatching SuperHyperPolynomial $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the neutrosophic SuperHyperPolynomial contains the neutrosophic coefficients defined as the neutrosophic number of the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of high neutrosophic cardinality neutrosophic SuperHyperVertices such that there's no neutrosophic SuperHyperVertex not to in a neutrosophic SuperHyperEdge and there's no neutrosophic SuperHyperEdge to have a neutrosophic SuperHyperVertex in a neutrosophic SuperHyperEdge and the neutrosophic power is neutrosophicly corresponded to its neutrosophic coefficient.
Assume a SuperHyperGraph. Then $\delta-$SuperHyperMatching is a maximal of SuperHyperVertices with a maximum cardinality such that either of the following expressions hold for the (neutrosophic) cardinalities of SuperHyperNeighbors of $s\in S:$ there are $|S\cap N(s)| > |S\cap (V\setminus N(s))|+\delta;$ and $ |S\cap N(s)| < |S\cap (V\setminus N(s))|+\delta.$
The first Expression, holds if $S$ is an $\delta-$SuperHyperOffensive. And the second Expression, holds if $S$ is an $\delta-$SuperHyperDefensive; a neutrosophic $\delta-$SuperHyperMatching is a maximal neutrosophic of SuperHyperVertices with maximum neutrosophic cardinality such that either of the following expressions hold for the neutrosophic cardinalities of SuperHyperNeighbors of $s\in S$ there are: $|S\cap N(s)|_{neutrosophic} > |S\cap (V\setminus N(s))|_{neutrosophic}+\delta;$ and
$ |S\cap N(s)|_{neutrosophic} < |S\cap (V\setminus N(s))|_{neutrosophic}+\delta.$
The first Expression, holds if $S$ is a neutrosophic $\delta-$SuperHyperOffensive. And the second Expression, holds if $S$ is a neutrosophic $\delta-$SuperHyperDefensive
It's useful to define a ``neutrosophic'' version of a SuperHyperMatching . Since there's more ways to get type-results to make a SuperHyperMatching more understandable. For the sake of having neutrosophic SuperHyperMatching, there's a need to ``redefine'' the notion of a ``SuperHyperMatching ''. The SuperHyperVertices and the SuperHyperEdges are assigned by the labels from the letters of the alphabets. In this procedure, there's the usage of the position of labels to assign to the values. Assume a SuperHyperMatching . It's redefined a neutrosophic SuperHyperMatching if the mentioned Table holds, concerning, ``The Values of Vertices, SuperVertices, Edges, HyperEdges, and SuperHyperEdges Belong to The Neutrosophic SuperHyperGraph'' with the key points,
``The Values of The Vertices \& The Number of Position in Alphabet'',
``The Values of The SuperVertices\&The maximum Values of Its Vertices'',
``The Values of The Edges\&The maximum Values of Its Vertices'',
``The Values of The HyperEdges\&The maximum Values of Its Vertices'', ``The Values of The SuperHyperEdges\&The maximum Values of Its Endpoints''. To get structural examples and instances, I'm going to introduce the next SuperHyperClass of SuperHyperGraph based on a SuperHyperMatching . It's the main. It'll be disciplinary to have the foundation of previous definition in the kind of SuperHyperClass. If there's a need to have all SuperHyperConnectivities until the SuperHyperMatching, then it's officially called a ``SuperHyperMatching'' but otherwise, it isn't a SuperHyperMatching . There are some instances about the clarifications for the main definition titled a ``SuperHyperMatching ''. These two examples get more scrutiny and discernment since there are characterized in the disciplinary ways of the SuperHyperClass based on a SuperHyperMatching . For the sake of having a neutrosophic SuperHyperMatching, there's a need to ``redefine'' the notion of a ``neutrosophic SuperHyperMatching'' and a ``neutrosophic SuperHyperMatching ''. The SuperHyperVertices and the SuperHyperEdges are assigned by the labels from the letters of the alphabets. In this procedure, there's the usage of the position of labels to assign to the values. Assume a neutrosophic SuperHyperGraph. It's redefined ``neutrosophic SuperHyperGraph'' if the intended Table holds. And a SuperHyperMatching are redefined to a ``neutrosophic SuperHyperMatching'' if the intended Table holds. It's useful to define ``neutrosophic'' version of SuperHyperClasses. Since there's more ways to get neutrosophic type-results to make a neutrosophic SuperHyperMatching more understandable. Assume a neutrosophic SuperHyperGraph. There are some neutrosophic SuperHyperClasses if the intended Table holds. Thus SuperHyperPath, SuperHyperCycle, SuperHyperStar, SuperHyperBipartite, SuperHyperMultiPartite, and SuperHyperWheel, are
``neutrosophic SuperHyperPath'', ``neutrosophic SuperHyperCycle'', ``neutrosophic SuperHyperStar'', ``neutrosophic SuperHyperBipartite'', ``neutrosophic SuperHyperMultiPartite'', and ``neutrosophic SuperHyperWheel'' if the intended Table holds. A SuperHyperGraph has a ``neutrosophic SuperHyperMatching'' where it's the strongest [the maximum neutrosophic value from all the SuperHyperMatching amid the maximum value amid all SuperHyperVertices from a SuperHyperMatching .] SuperHyperMatching . A graph is a SuperHyperUniform if it's a SuperHyperGraph and the number of elements of SuperHyperEdges are the same. Assume a neutrosophic SuperHyperGraph. There are some SuperHyperClasses as follows. It's SuperHyperPath if it's only one SuperVertex as intersection amid two given SuperHyperEdges with two exceptions; it's SuperHyperCycle if it's only one SuperVertex as intersection amid two given SuperHyperEdges; it's SuperHyperStar it's only one SuperVertex as intersection amid all SuperHyperEdges;
it's SuperHyperBipartite it's only one SuperVertex as intersection amid two given SuperHyperEdges and these SuperVertices, forming two separate sets, has no SuperHyperEdge in common; it's SuperHyperMultiPartite it's only one SuperVertex as intersection amid two given SuperHyperEdges and these SuperVertices, forming multi separate sets, has no SuperHyperEdge in common; it's a SuperHyperWheel if it's only one SuperVertex as intersection amid two given SuperHyperEdges and one SuperVertex has one SuperHyperEdge with any common SuperVertex. The SuperHyperModel proposes the specific designs and the specific architectures. The SuperHyperModel is officially called ``SuperHyperGraph'' and ``Neutrosophic SuperHyperGraph''. In this SuperHyperModel, The ``specific'' cells and ``specific group'' of cells are SuperHyperModeled as ``SuperHyperVertices'' and the common and intended properties between ``specific'' cells and ``specific group'' of cells are SuperHyperModeled as ``SuperHyperEdges''. Sometimes, it's useful to have some degrees of determinacy, indeterminacy, and neutrality to have more precise SuperHyperModel which in this case the SuperHyperModel is called ``neutrosophic''. In the future research, the foundation will be based on the ``Cancer's Recognition'' and the results and the definitions will be introduced in redeemed ways. The recognition of the cancer in the long-term function. The specific region has been assigned by the model [it's called SuperHyperGraph] and the long cycle of the move from the cancer is identified by this research. Sometimes the move of the cancer hasn't be easily identified since there are some determinacy, indeterminacy and neutrality about the moves and the effects of the cancer on that region; this event leads us to choose another model [it's said to be neutrosophic SuperHyperGraph] to have convenient perception on what's happened and what's done. There are some specific models, which are well-known and they've got the names, and some SuperHyperGeneral SuperHyperModels. The moves and the traces of the cancer on the complex tracks and between complicated groups of cells could be fantasized by a neutrosophic SuperHyperPath(-/SuperHyperCycle, SuperHyperStar, SuperHyperBipartite, SuperHyperMultipartite, SuperHyperWheel). The aim is to find either the longest SuperHyperMatching or the strongest SuperHyperMatching in those neutrosophic SuperHyperModels. For the longest SuperHyperMatching, called SuperHyperMatching, and the strongest SuperHyperMatching, called neutrosophic SuperHyperMatching, some general results are introduced. Beyond that in SuperHyperStar, all possible SuperHyperPaths have only two SuperHyperEdges but it's not enough since it's essential to have at least three SuperHyperEdges to form any style of a SuperHyperCycle. There isn't any formation of any SuperHyperCycle but literarily, it's the deformation of any SuperHyperCycle. It, literarily, deforms and it doesn't form. A basic familiarity with neutrosophic SuperHyperMatching theory, SuperHyperGraphs, and Neutrosophic SuperHyperGraphs theory are proposed.
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\textbf{Keywords:} Neutrosophic SuperHyperGraph, (Neutrosophic) SuperHyperMatching, Cancer's Neutrosophic Recognition
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\textbf{AMS Subject Classification:} 05C17, 05C22, 05E45
\section{Background}
There are some researches covering the topic of this research. In what follows, there are some discussion and literature reviews about them.
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First article is titled ``properties of SuperHyperGraph and neutrosophic SuperHyperGraph'' in \textbf{Ref.} \cite{HG1} by Henry Garrett (2022). It's first step toward the research on neutrosophic SuperHyperGraphs. This research article is published on the journal ``Neutrosophic Sets and Systems'' in issue 49 and the pages 531-561. In this research article, different types of notions like dominating, resolving, coloring, Eulerian(Hamiltonian) neutrosophic path, n-Eulerian(Hamiltonian) neutrosophic path, zero forcing number, zero forcing neutrosophic- number, independent number, independent neutrosophic-number, clique number, clique neutrosophic-number, matching number, matching neutrosophic-number, girth, neutrosophic girth, 1-zero-forcing number, 1-zero- forcing neutrosophic-number, failed 1-zero-forcing number, failed 1-zero-forcing neutrosophic-number, global- offensive alliance, t-offensive alliance, t-defensive alliance, t-powerful alliance, and global-powerful alliance are defined in SuperHyperGraph and neutrosophic SuperHyperGraph. Some Classes of SuperHyperGraph and Neutrosophic SuperHyperGraph are cases of research. Some results are applied in family of SuperHyperGraph and neutrosophic SuperHyperGraph. Thus this research article has concentrated on the vast notions and introducing the majority of notions.
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The seminal paper and groundbreaking article is titled
``neutrosophic co-degree and neutrosophic degree alongside chromatic numbers in the setting of some classes related to neutrosophic hypergraphs'' in \textbf{Ref.} \cite{HG2} by Henry Garrett (2022). In this research article, a novel approach is implemented on SuperHyperGraph and neutrosophic SuperHyperGraph based on general forms without using neutrosophic classes of neutrosophic SuperHyperGraph. It's published in prestigious and fancy journal is entitled “Journal of Current Trends in Computer Science Research (JCTCSR)” with abbreviation ``J Curr Trends Comp Sci Res'' in volume 1 and issue 1 with pages 06-14. The research article studies deeply with choosing neutrosophic hypergraphs instead of neutrosophic SuperHyperGraph. It's the breakthrough toward independent results based on initial background.
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The seminal paper and groundbreaking article is titled
``Super Hyper Dominating and Super Hyper Resolving on Neutrosophic Super Hyper Graphs and Their Directions in Game Theory and Neutrosophic Super Hyper Classes'' in \textbf{Ref.} \cite{HG3} by Henry Garrett (2022). In this research article, a novel approach is implemented on SuperHyperGraph and neutrosophic SuperHyperGraph based on fundamental SuperHyperNumber and using neutrosophic SuperHyperClasses of neutrosophic SuperHyperGraph. It's published in prestigious and fancy journal is entitled “Journal of Mathematical Techniques and Computational Mathematics(JMTCM)” with abbreviation ``J Math Techniques Comput Math'' in volume 1 and issue 3 with pages 242-263. The research article studies deeply with choosing directly neutrosophic SuperHyperGraph and SuperHyperGraph. It's the breakthrough toward independent results based on initial background and fundamental SuperHyperNumbers.
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In some articles are titled ``0039 | Closing Numbers and Super-Closing Numbers as (Dual)Resolving and (Dual)Coloring alongside (Dual)Dominating in (Neutrosophic)n-SuperHyperGraph'' in \textbf{Ref.} \cite{HG4} by Henry Garrett (2022), ``0049 | (Failed)1-Zero-Forcing Number in Neutrosophic Graphs'' in \textbf{Ref.} \cite{HG5} by Henry Garrett (2022), ``Neutrosophic Failed SuperHyperStable as the Survivors on the Cancer's Neutrosophic Recognition Based on Uncertainty to All Modes in Neutrosophic SuperHyperGraphs'' in \textbf{Ref.} \cite{HG6} by Henry Garrett (2022), ``Extremism of the Attacked Body Under the Cancer's Circumstances Where Cancer's Recognition Titled (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG7} by Henry Garrett (2022), ``(Neutrosophic) 1-Failed SuperHyperForcing in Cancer’s Recognitions And (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG8} by Henry Garrett (2022), ``Neutrosophic Messy-Style SuperHyperGraphs To Form Neutrosophic SuperHyperStable To Act on Cancer’s Neutrosophic Recognitions In Special ViewPoints'' in \textbf{Ref.} \cite{HG9} by Henry Garrett (2022), ``Neutrosophic 1-Failed SuperHyperForcing in the SuperHyperFunction To Use Neutrosophic SuperHyperGraphs on Cancer’s Neutrosophic Recognition And Beyond'' in \textbf{Ref.} \cite{HG10} by Henry Garrett (2022), ``(Neutrosophic) SuperHyperStable on Cancer’s Recognition by Well- SuperHyperModelled (Neutrosophic) SuperHyperGraphs
'' in \textbf{Ref.} \cite{HG11} by Henry Garrett (2022), ``Neutrosophic Messy-Style SuperHyperGraphs To Form Neutrosophic SuperHyperStable To Act on Cancer’s Neutrosophic Recognitions In Special ViewPoints'' in \textbf{Ref.} \cite{HG12} by Henry Garrett (2022), ``Basic Notions on (Neutrosophic) SuperHyperForcing And (Neutrosophic) SuperHyperModeling in Cancer’s Recognitions And (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG13} by Henry Garrett (2022), ``(Neutrosophic) SuperHyperModeling of Cancer’s Recognitions Featuring (Neutrosophic) SuperHyperDefensive SuperHyperAlliances'' in \textbf{Ref.} \cite{HG14} by Henry Garrett (2022), ``(Neutrosophic) SuperHyperAlliances With SuperHyperDefensive and SuperHyperOffensive Type-SuperHyperSet On (Neutrosophic) SuperHyperGraph With (Neutrosophic) SuperHyperModeling of Cancer’s Recognitions And Related (Neutrosophic) SuperHyperClasses'' in \textbf{Ref.} \cite{HG15} by Henry Garrett (2022), ``SuperHyperGirth on SuperHyperGraph and Neutrosophic SuperHyperGraph With SuperHyperModeling of Cancer’s Recognitions'' in \textbf{Ref.} \cite{HG16} by Henry Garrett (2022), ``Some SuperHyperDegrees and Co-SuperHyperDegrees on Neutrosophic SuperHyperGraphs and SuperHyperGraphs Alongside Applications in Cancer’s Treatments'' in \textbf{Ref.} \cite{HG17} by Henry Garrett (2022), ``SuperHyperDominating and SuperHyperResolving on Neutrosophic SuperHyperGraphs And Their Directions in Game Theory and Neutrosophic SuperHyperClasses'' in \textbf{Ref.} \cite{HG18} by Henry Garrett (2022), ``The Focus on The Partitions Obtained By Parallel Moves In The Cancer's Extreme Recognition With Different Types of Extreme SuperHyperMatching Set and Polynomial on (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG19} by Henry Garrett (2023), ``Extreme Failed SuperHyperClique Decides the Failures on the Cancer's Recognition in the Perfect Connections of Cancer's Attacks By SuperHyperModels Named (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG20} by Henry Garrett (2023), ``Indeterminacy On The All Possible Connections of Cells In Front of Cancer's Attacks In The Terms of Neutrosophic Failed SuperHyperClique on Cancer's Recognition called Neutrosophic SuperHyperGraphs'' in \textbf{Ref.} \cite{HG21} by Henry Garrett (2023), ``Perfect Directions Toward Idealism in Cancer's Neutrosophic Recognition Forwarding Neutrosophic SuperHyperClique on Neutrosophic SuperHyperGraphs'' in \textbf{Ref.} \cite{HG22} by Henry Garrett (2023), ``Demonstrating Complete Connections in Every Embedded Regions and Sub-Regions in the Terms of Cancer's Recognition and (Neutrosophic) SuperHyperGraphs With (Neutrosophic) SuperHyperClique'' in \textbf{Ref.} \cite{HG23} by Henry Garrett (2023), ``Different Neutrosophic Types of Neutrosophic Regions titled neutrosophic Failed SuperHyperStable in Cancer’s Neutrosophic Recognition modeled in the Form of Neutrosophic SuperHyperGraphs'' in \textbf{Ref.} \cite{HG24} by Henry Garrett (2023), ``Using the Tool As (Neutrosophic) Failed SuperHyperStable To SuperHyperModel Cancer's Recognition Titled (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG25} by Henry Garrett (2023), ``Neutrosophic Messy-Style SuperHyperGraphs To Form Neutrosophic SuperHyperStable To Act on Cancer’s Neutrosophic Recognitions In Special ViewPoints'' in \textbf{Ref.} \cite{HG26} by Henry Garrett (2023), ``(Neutrosophic) SuperHyperStable on Cancer’s Recognition by Well-SuperHyperModelled (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG27} by Henry Garrett (2023), ``Neutrosophic 1-Failed SuperHyperForcing in the SuperHyperFunction To Use Neutrosophic SuperHyperGraphs on Cancer’s Neutrosophic Recognition And Beyond'' in \textbf{Ref.} \cite{HG28} by Henry Garrett (2022), ``(Neutrosophic) 1-Failed SuperHyperForcing in Cancer’s Recognitions And (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG29} by Henry Garrett (2022), ``Basic Notions on (Neutrosophic) SuperHyperForcing And (Neutrosophic) SuperHyperModeling in Cancer’s Recognitions And (Neutrosophic) SuperHyperGraphs'' in \textbf{Ref.} \cite{HG30} by Henry Garrett (2022), ``Basic Neutrosophic Notions Concerning SuperHyperDominating and Neutrosophic SuperHyperResolving in SuperHyperGraph'' in \textbf{Ref.} \cite{HG31} by Henry Garrett (2022), ``Initial Material of Neutrosophic Preliminaries to Study Some Neutrosophic Notions Based on Neutrosophic SuperHyperEdge (NSHE) in Neutrosophic SuperHyperGraph (NSHG)'' in \textbf{Ref.} \cite{HG32} by Henry Garrett (2022), there are some endeavors to formalize the basic SuperHyperNotions about neutrosophic SuperHyperGraph and SuperHyperGraph.
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Some studies and researches about neutrosophic graphs, are proposed as book in \textbf{Ref.} \cite{HG33} by Henry Garrett (2022) which is indexed by Google Scholar and has more than 2347 readers in Scribd. It's titled ``Beyond Neutrosophic Graphs'' and published by Ohio: E-publishing: Educational Publisher 1091 West 1st Ave Grandview Heights, Ohio 43212 United State. This research book covers different types of notions and settings in neutrosophic graph theory and neutrosophic SuperHyperGraph theory.
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Also, some studies and researches about neutrosophic graphs, are proposed as book in \textbf{Ref.} \cite{HG34} by Henry Garrett (2022) which is indexed by Google Scholar and has more than 3048 readers in Scribd. It's titled ``Neutrosophic Duality'' and published by Florida: GLOBAL KNOWLEDGE - Publishing House 848 Brickell Ave Ste 950 Miami, Florida 33131 United States. This research book presents different types of notions SuperHyperResolving and SuperHyperDominating in the setting of duality in neutrosophic graph theory and neutrosophic SuperHyperGraph theory. This research book has scrutiny on the complement of the intended set and the intended set, simultaneously. It's smart to consider a set but acting on its complement that what's done in this research book which is popular in the terms of high readers in Scribd.
\section{Motivation and Contributions}
In this research, there are some ideas in the featured frameworks of motivations. I try to bring the motivations in the narrative ways. Some cells have been faced with some attacks from the situation which is caused by the cancer's attacks. In this case, there are some embedded analysis on the ongoing situations which in that, the cells could be labelled as some groups and some groups or individuals have excessive labels which all are raised from the behaviors to overcome the cancer's attacks. In the embedded situations, the individuals of cells and the groups of cells could be considered as ``new groups''. Thus it motivates us to find the proper SuperHyperModels for getting more proper analysis on this messy story. I've found the SuperHyperModels which are officially called ``SuperHyperGraphs'' and ``Neutrosophic SuperHyperGraphs''. In this SuperHyperModel, the cells and the groups of cells are defined as ``SuperHyperVertices'' and the relations between the individuals of cells and the groups of cells are defined as ``SuperHyperEdges''. Thus it's another motivation for us to do research on this SuperHyperModel based on the ``Cancer's Recognition''. Sometimes, the situations get worst. The situation is passed from the certainty and precise style. Thus it's the beyond them. There are three descriptions, namely, the degrees of determinacy, indeterminacy and neutrality, for any object based on vague forms, namely, incomplete data, imprecise data, and uncertain analysis. The latter model could be considered on the previous SuperHyperModel. It's SuperHyperModel. It's SuperHyperGraph but it's officially called ``Neutrosophic SuperHyperGraphs''. The cancer is the disease but the model is going to figure out what's going on this phenomenon. The special case of this disease is considered and as the consequences of the model, some parameters are used. The cells are under attack of this disease but the moves of the cancer in the special region are the matter of mind. The recognition of the cancer could help to find some treatments for this disease. The SuperHyperGraph and neutrosophic SuperHyperGraph are the SuperHyperModels on the ``Cancer's Recognition'' and both bases are the background of this research. Sometimes the cancer has been happened on the region, full of cells, groups of cells and embedded styles. In this segment, the SuperHyperModel proposes some SuperHyperNotions based on the connectivities of the moves of the cancer in the forms of alliances' styles with the formation of the design and the architecture are formally called `` SuperHyperMatching'' in the themes of jargons and buzzwords. The prefix ``SuperHyper'' refers to the theme of the embedded styles to figure out the background for the SuperHyperNotions. The recognition of the cancer in the long-term function. The specific region has been assigned by the model [it's called SuperHyperGraph] and the long cycle of the move from the cancer is identified by this research. Sometimes the move of the cancer hasn't be easily identified since there are some determinacy, indeterminacy and neutrality about the moves and the effects of the cancer on that region; this event leads us to choose another model [it's said to be neutrosophic SuperHyperGraph] to have convenient perception on what's happened and what's done. There are some specific models, which are well-known and they've got the names, and some general models. The moves and the traces of the cancer on the complex tracks and between complicated groups of cells could be fantasized by a neutrosophic neutrosophic SuperHyperPath (-/SuperHyperCycle, SuperHyperStar, SuperHyperBipartite, SuperHyperMultipartite, SuperHyperWheel). The aim is to find either the optimal SuperHyperMatching or the neutrosophic SuperHyperMatching in those neutrosophic SuperHyperModels. Some general results are introduced. Beyond that in SuperHyperStar, all possible neutrosophic SuperHyperPath s have only two SuperHyperEdges but it's not enough since it's essential to have at least three SuperHyperEdges to form any style of a SuperHyperCycle. There isn't any formation of any SuperHyperCycle but literarily, it's the deformation of any SuperHyperCycle. It, literarily, deforms and it doesn't form.
\begin{question}
How to define the SuperHyperNotions and to do research on them to find the `` amount of SuperHyperMatching'' of either individual of cells or the groups of cells based on the fixed cell or the fixed group of cells, extensively, the ``amount of SuperHyperMatching'' based on the fixed groups of cells or the fixed groups of group of cells?
\end{question}
\begin{question}
What are the best descriptions for the ``Cancer's Recognition'' in terms of these messy and dense SuperHyperModels where embedded notions are illustrated?
\end{question}
It's motivation to find notions to use in this dense model is titled ``SuperHyperGraphs''. Thus it motivates us to define different types of `` SuperHyperMatching'' and ``neutrosophic SuperHyperMatching'' on ``SuperHyperGraph'' and ``Neutrosophic SuperHyperGraph''. Then the research has taken more motivations to define SuperHyperClasses and to find some connections amid this SuperHyperNotion with other SuperHyperNotions. It motivates us to get some instances and examples to make clarifications about the framework of this research. The general results and some results about some connections are some avenues to make key point of this research, ``Cancer's Recognition'', more understandable and more clear.
\\
The framework of this research is as follows. In the beginning, I introduce basic definitions to clarify about preliminaries. In the subsection ``Preliminaries'', initial definitions about SuperHyperGraphs and neutrosophic SuperHyperGraph are deeply-introduced and in-depth-discussed. The elementary concepts are clarified and illustrated completely and sometimes review literature are applied to make sense about what's going to figure out about the upcoming sections. The main definitions and their clarifications alongside some results about new notions, SuperHyperMatching and neutrosophic SuperHyperMatching, are figured out in sections `` SuperHyperMatching'' and ``Neutrosophic SuperHyperMatching''. In the sense of tackling on getting results and in order to make sense about continuing the research, the ideas of SuperHyperUniform and Neutrosophic SuperHyperUniform are introduced and as their consequences, corresponded SuperHyperClasses are figured out to debut what's done in this section, titled ``Results on SuperHyperClasses'' and ``Results on Neutrosophic SuperHyperClasses''. As going back to origin of the notions, there are some smart steps toward the common notions to extend the new notions in new frameworks, SuperHyperGraph and Neutrosophic SuperHyperGraph, in the sections ``Results on SuperHyperClasses'' and ``Results on Neutrosophic SuperHyperClasses''. The starter research about the general SuperHyperRelations and as concluding and closing section of theoretical research are contained in the section ``General Results''. Some general SuperHyperRelations are fundamental and they are well-known as fundamental SuperHyperNotions as elicited and discussed in the sections, ``General Results'',
`` SuperHyperMatching'', ``Neutrosophic SuperHyperMatching'', ``Results on SuperHyperClasses'' and ``Results on Neutrosophic SuperHyperClasses''. There are curious questions about what's done about the SuperHyperNotions to make sense about excellency of this research and going to figure out the word ``best'' as the description and adjective for this research as presented in section, `` SuperHyperMatching''. The keyword of this research debut in the section ``Applications in Cancer's Recognition'' with two cases and subsections ``Case 1: The Initial Steps Toward SuperHyperBipartite as SuperHyperModel'' and ``Case 2: The Increasing Steps Toward SuperHyperMultipartite as SuperHyperModel''. In the section, ``Open Problems'', there are some scrutiny and discernment on what's done and what's happened in this research in the terms of ``questions'' and ``problems'' to make sense to figure out this research in featured style. The advantages and the limitations of this research alongside about what's done in this research to make sense and to get sense about what's figured out are included in the section, ``Conclusion and Closing Remarks''.
\section{Preliminaries}
In this subsection, the basic material which is used in this research, is presented. Also, the new ideas and their clarifications are elicited.
\begin{definition}[Neutrosophic Set](\textbf{Ref.}\cite{2},Definition 2.1,p.87).\\
Let $X$ be a space of points (objects) with generic elements in $X$ denoted by $x;$ then the \textbf{neutrosophic set} $A$ (NS $A$) is an object having the form
$$A = \{< x:T_A(x),I_A(x),F_A(x)>, x\in X\}$$
where the functions $T, I, F: X\rightarrow]^-0,1\leftidx{^+}{[}$ define respectively the a \textbf{truth-membership function}, an \textbf{indeterminacy-membership function}, and a \textbf{falsity-membership function} of the element $x\in X$ to the set $A$ with the condition
$$\leftidx{^-}{0} \leq T_A(x)+I_A(x)+F_A(x)\leq 3^{+}.$$
The functions $T_A(x),I_A(x)$ and $F_A(x)$ are real standard or nonstandard subsets of $]^-0,1\leftidx{^+}{[}.$
\end{definition}
\begin{definition}[Single Valued Neutrosophic Set](\textbf{Ref.}\cite{5},Definition 6,p.2).\\
Let $X$ be a space of points (objects) with generic elements in $X$ denoted by $x.$ A \textbf{single valued neutrosophic set} $A$ (SVNS $A$) is characterized by truth-membership function $T_A(x),$ an indeterminacy-membership function $I_A(x),$ and a falsity-membership function $F_A(x).$ For each point $x$ in $X,$ $T_A(x),I_A(x),F_A(x)\in [0,1].$ A SVNS $A$ can be written as
$$A = \{< x:T_A(x),I_A(x),F_A(x)>, x\in X\}.$$
\end{definition}
\begin{definition}
The \textbf{degree of truth-membership}, \textbf{indeterminacy-membership} and \textbf{falsity-membership of the subset} $X\subset A$ of the single valued neutrosophic set $A = \{< x:T_A(x),I_A(x),F_A(x)>, x\in X\}$:$$T_A(X)=\min[T_A(v_i),T_A(v_j)]_{v_i,v_j\in X},$$
$$I_A(X)=\min[I_A(v_i),I_A(v_j)]_{v_i,v_j\in X},$$
$$ \text{and}~F_A(X)=\min[F_A(v_i),F_A(v_j)]_{v_i,v_j\in X}.$$
\end{definition}
\begin{definition}
The \textbf{support} of $X\subset A$ of the single valued neutrosophic set $A = \{< x:T_A(x),I_A(x),F_A(x)>, x\in X\}$:
$$supp(X)=\{x\in X:~T_A(x),I_A(x),F_A(x)> 0\}.$$
\end{definition}
\begin{definition}[Neutrosophic SuperHyperGraph (NSHG)](\textbf{Ref.}\cite{4},Definition 3,p.291).\\
Assume $V'$ is a given set. A \textbf{neutrosophic SuperHyperGraph} (NSHG) $S$
is an ordered pair $S=(V,E),$ where
\begin{itemize}
\item[$(i)$] $V=\{V_1,V_2,\ldots,V_n\}$ a finite set of finite single valued neutrosophic subsets of $V';$
\item[$(ii)$] $V=\{(V_i,T_{V'}(V_i),I_{V'}(V_i),F_{V'}(V_i)):~T_{V'}(V_i),I_{V'}(V_i),F_{V'}(V_i)\geq0\},~(i=1,2,\ldots,n);$
\item[$(iii)$] $E=\{E_1,E_2,\ldots,E_{n'}\}$ a finite set of finite single valued neutrosophic subsets of $V;$
\item[$(iv)$] $E=\{(E_{i'},T'_{V}(E_{i'}),I'_{V}(E_{i'}),F'_{V}(E_{i'})):~T'_{V}(E_{i'}),I'_{V}(E_{i'}),F'_{V}(E_{i'})\geq0\},~(i'=1,2,\ldots,n');$
\item[$(v)$] $V_i\neq\emptyset,~(i=1,2,\ldots,n);$
\item[$(vi)$] $E_{i'}\neq\emptyset,~(i'=1,2,\ldots,n');$
\item[$(vii)$] $\sum_{i}supp(V_i)=V,~(i=1,2,\ldots,n);$
\item[$(viii)$] $\sum_{i'}supp(E_{i'})=V,~(i'=1,2,\ldots,n');$
\item[$(ix)$] and the following conditions hold:
$$T'_V(E_{i'})\leq\min[T_{V'}(V_i),T_{V'}(V_j)]_{V_i,V_j\in E_{i'}},$$
$$ I'_V(E_{i'})\leq\min[I_{V'}(V_i),I_{V'}(V_j)]_{V_i,V_j\in E_{i'}},$$
$$ \text{and}~F'_V(E_{i'})\leq\min[F_{V'}(V_i),F_{V'}(V_j)]_{V_i,V_j\in E_{i'}}$$
where $i'=1,2,\ldots,n'.$
\end{itemize}
Here the neutrosophic SuperHyperEdges (NSHE) $E_{j'}$ and the neutrosophic SuperHyperVertices (NSHV) $V_j$ are single valued neutrosophic sets. $T_{V'}(V_i),I_{V'}(V_i),$ and $F_{V'}(V_i)$ denote the degree of truth-membership, the degree of indeterminacy-membership and the degree of falsity-membership the neutrosophic SuperHyperVertex (NSHV) $V_i$ to the neutrosophic SuperHyperVertex (NSHV) $V.$ $T'_{V}(E_{i'}),T'_{V}(E_{i'}),$ and $T'_{V}(E_{i'})$ denote the degree of truth-membership, the degree of indeterminacy-membership and the degree of falsity-membership of the neutrosophic SuperHyperEdge (NSHE) $E_{i'}$ to the neutrosophic SuperHyperEdge (NSHE) $E.$ Thus, the $ii'$th element of the \textbf{incidence matrix} of neutrosophic SuperHyperGraph (NSHG) are of the form $(V_i,T'_{V}(E_{i'}),I'_{V}(E_{i'}),F'_{V}(E_{i'}))$, the sets V and E are crisp sets.
\end{definition}
\begin{definition}[Characterization of the Neutrosophic SuperHyperGraph (NSHG)](\textbf{Ref.}\cite{4},Section 4,pp.291-292).\\
Assume a neutrosophic SuperHyperGraph (NSHG) $S$
is an ordered pair $S=(V,E).$ The neutrosophic SuperHyperEdges (NSHE) $E_{i'}$ and the neutrosophic SuperHyperVertices (NSHV) $V_i$ of neutrosophic SuperHyperGraph (NSHG) $S=(V,E)$ could be characterized as follow-up items.
\begin{itemize}
\item[$(i)$] If $|V_i|=1,$ then $V_i$ is called \textbf{vertex};
\item[$(ii)$] if $|V_i|\geq1,$ then $V_i$ is called \textbf{SuperVertex};
\item[$(iii)$] if for all $V_i$s are incident in $E_{i'},$ $|V_i|=1,$ and $|E_{i'}|=2,$ then $E_{i'}$ is called \textbf{edge};
\item[$(iv)$] if for all $V_i$s are incident in $E_{i'},$ $|V_i|=1,$ and $|E_{i'}|\geq2,$ then $E_{i'}$ is called \textbf{HyperEdge};
\item[$(v)$] if there's a $V_i$ is incident in $E_{i'}$ such that $|V_i|\geq1,$ and $|E_{i'}|=2,$ then $E_{i'}$ is called \textbf{SuperEdge};
\item[$(vi)$] if there's a $V_i$ is incident in $E_{i'}$ such that $|V_i|\geq1,$ and $|E_{i'}|\geq2,$ then $E_{i'}$ is called \textbf{SuperHyperEdge}.
\end{itemize}
\end{definition}
If we choose different types of binary operations, then we could get hugely diverse types of general forms of neutrosophic SuperHyperGraph (NSHG).
\begin{definition}[t-norm](\textbf{Ref.}\cite{3}, Definition 5.1.1, pp.82-83).\\
A binary operation $\otimes: [0, 1] \times [0, 1] \rightarrow [0, 1]$ is a \textbf{$t$-norm} if it satisfies the following for $x,y,z,w \in [0, 1]$:
\begin{itemize}
\item[$(i)$] $1 \otimes x =x;$
\item[$(ii)$] $x \otimes y = y \otimes x;$
\item[$(iii)$] $x \otimes (y \otimes z) = (x \otimes y) \otimes z;$
\item[$(iv)$] If $ w \leq x$ and $y \leq z$ then $w \otimes y \leq x \otimes z.$
\end{itemize}
\end{definition}
\begin{definition}
The \textbf{degree of truth-membership}, \textbf{indeterminacy-membership} and \textbf{falsity-membership of the subset} $X\subset A$ of the single valued neutrosophic set $A = \{< x:T_A(x),I_A(x),F_A(x)>, x\in X\}$ (with respect to t-norm $T_{norm}$):$$T_A(X)=T_{norm}[T_A(v_i),T_A(v_j)]_{v_i,v_j\in X},$$
$$I_A(X)=T_{norm}[I_A(v_i),I_A(v_j)]_{v_i,v_j\in X},$$
$$ \text{and}~F_A(X)=T_{norm}[F_A(v_i),F_A(v_j)]_{v_i,v_j\in X}.$$
\end{definition}
\begin{definition}
The \textbf{support} of $X\subset A$ of the single valued neutrosophic set $A = \{< x:T_A(x),I_A(x),F_A(x)>, x\in X\}$:
$$supp(X)=\{x\in X:~T_A(x),I_A(x),F_A(x)> 0\}.$$
\end{definition}
\begin{definition}(General Forms of Neutrosophic SuperHyperGraph (NSHG)).\\
Assume $V'$ is a given set. A \textbf{neutrosophic SuperHyperGraph} (NSHG) $S$
is an ordered pair $S=(V,E),$ where
\begin{itemize}
\item[$(i)$] $V=\{V_1,V_2,\ldots,V_n\}$ a finite set of finite single valued neutrosophic subsets of $V';$
\item[$(ii)$] $V=\{(V_i,T_{V'}(V_i),I_{V'}(V_i),F_{V'}(V_i)):~T_{V'}(V_i),I_{V'}(V_i),F_{V'}(V_i)\geq0\},~(i=1,2,\ldots,n);$
\item[$(iii)$] $E=\{E_1,E_2,\ldots,E_{n'}\}$ a finite set of finite single valued neutrosophic subsets of $V;$
\item[$(iv)$] $E=\{(E_{i'},T'_{V}(E_{i'}),I'_{V}(E_{i'}),F'_{V}(E_{i'})):~T'_{V}(E_{i'}),I'_{V}(E_{i'}),F'_{V}(E_{i'})\geq0\},~(i'=1,2,\ldots,n');$
\item[$(v)$] $V_i\neq\emptyset,~(i=1,2,\ldots,n);$
\item[$(vi)$] $E_{i'}\neq\emptyset,~(i'=1,2,\ldots,n');$
\item[$(vii)$] $\sum_{i}supp(V_i)=V,~(i=1,2,\ldots,n);$
\item[$(viii)$] $\sum_{i'}supp(E_{i'})=V,~(i'=1,2,\ldots,n').$
\end{itemize}
Here the neutrosophic SuperHyperEdges (NSHE) $E_{j'}$ and the neutrosophic SuperHyperVertices (NSHV) $V_j$ are single valued neutrosophic sets. $T_{V'}(V_i),I_{V'}(V_i),$ and $F_{V'}(V_i)$ denote the degree of truth-membership, the degree of indeterminacy-membership and the degree of falsity-membership the neutrosophic SuperHyperVertex (NSHV) $V_i$ to the neutrosophic SuperHyperVertex (NSHV) $V.$ $T'_{V}(E_{i'}),T'_{V}(E_{i'}),$ and $T'_{V}(E_{i'})$ denote the degree of truth-membership, the degree of indeterminacy-membership and the degree of falsity-membership of the neutrosophic SuperHyperEdge (NSHE) $E_{i'}$ to the neutrosophic SuperHyperEdge (NSHE) $E.$ Thus, the $ii'$th element of the \textbf{incidence matrix} of neutrosophic SuperHyperGraph (NSHG) are of the form $(V_i,T'_{V}(E_{i'}),I'_{V}(E_{i'}),F'_{V}(E_{i'}))$, the sets V and E are crisp sets.\end{definition}
\begin{definition}[Characterization of the Neutrosophic SuperHyperGraph (NSHG)](\textbf{Ref.}\cite{4},Section 4,pp.291-292).\\
Assume a neutrosophic SuperHyperGraph (NSHG) $S$
is an ordered pair $S=(V,E).$ The neutrosophic SuperHyperEdges (NSHE) $E_{i'}$ and the neutrosophic SuperHyperVertices (NSHV) $V_i$ of neutrosophic SuperHyperGraph (NSHG) $S=(V,E)$ could be characterized as follow-up items.
\begin{itemize}
\item[$(i)$] If $|V_i|=1,$ then $V_i$ is called \textbf{vertex};
\item[$(ii)$] if $|V_i|\geq1,$ then $V_i$ is called \textbf{SuperVertex};
\item[$(iii)$] if for all $V_i$s are incident in $E_{i'},$ $|V_i|=1,$ and $|E_{i'}|=2,$ then $E_{i'}$ is called \textbf{edge};
\item[$(iv)$] if for all $V_i$s are incident in $E_{i'},$ $|V_i|=1,$ and $|E_{i'}|\geq2,$ then $E_{i'}$ is called \textbf{HyperEdge};
\item[$(v)$] if there's a $V_i$ is incident in $E_{i'}$ such that $|V_i|\geq1,$ and $|E_{i'}|=2,$ then $E_{i'}$ is called \textbf{SuperEdge};
\item[$(vi)$] if there's a $V_i$ is incident in $E_{i'}$ such that $|V_i|\geq1,$ and $|E_{i'}|\geq2,$ then $E_{i'}$ is called \textbf{SuperHyperEdge}.
\end{itemize}
\end{definition}
This SuperHyperModel is too messy and too dense. Thus there's a need to have some restrictions and conditions on SuperHyperGraph. The special case of this SuperHyperGraph makes the patterns and regularities.
\begin{definition}
A graph is \textbf{SuperHyperUniform} if it's SuperHyperGraph and the number of elements of SuperHyperEdges are the same.
\end{definition}
To get more visions on , the some SuperHyperClasses are introduced. It makes to have more understandable.
\begin{definition}
Assume a neutrosophic SuperHyperGraph. There are some SuperHyperClasses as follows.
\begin{itemize}
\item[(i).] It's \textbf{neutrosophic SuperHyperPath } if it's only one SuperVertex as intersection amid two given SuperHyperEdges with two exceptions;
\item[(ii).] it's \textbf{SuperHyperCycle} if it's only one SuperVertex as intersection amid two given SuperHyperEdges;
\item[(iii).] it's \textbf{SuperHyperStar} it's only one SuperVertex as intersection amid all SuperHyperEdges;
\item[(iv).] it's \textbf{SuperHyperBipartite} it's only one SuperVertex as intersection amid two given SuperHyperEdges and these SuperVertices, forming two separate sets, has no SuperHyperEdge in common;
\item[(v).] it's \textbf{SuperHyperMultiPartite} it's only one SuperVertex as intersection amid two given SuperHyperEdges and these SuperVertices, forming multi separate sets, has no SuperHyperEdge in common;
\item[(vi).] it's \textbf{SuperHyperWheel} if it's only one SuperVertex as intersection amid two given SuperHyperEdges and one SuperVertex has one SuperHyperEdge with any common SuperVertex.
\end{itemize}
\end{definition}
\begin{definition}
Let an ordered pair $S=(V,E)$ be a neutrosophic SuperHyperGraph (NSHG) $S.$ Then a sequence of neutrosophic SuperHyperVertices (NSHV) and neutrosophic SuperHyperEdges (NSHE)
$$V_1,E_1,V_2,E_2,V_3,\ldots,V_{s-1},E_{s-1},V_s$$
is called a \textbf{neutrosophic neutrosophic SuperHyperPath } (NSHP) from neutrosophic SuperHyperVertex (NSHV) $V_1$ to neutrosophic SuperHyperVertex (NSHV) $V_s$ if either of following conditions hold:
\begin{itemize}
\item[$(i)$] $V_i,V_{i+1}\in E_{i'};$
\item[$(ii)$] there's a vertex $v_i\in V_i$ such that $v_i,V_{i+1}\in E_{i'};$
\item[$(iii)$] there's a SuperVertex $V'_i \in V_i$ such that $V'_i,V_{i+1}\in E_{i'};$
\item[$(iv)$] there's a vertex $v_{i+1}\in V_{i+1}$ such that $V_i,v_{i+1}\in E_{i'};$
\item[$(v)$] there's a SuperVertex $V'_{i+1} \in V_{i+1}$ such that $V_i,V'_{i+1}\in E_{i'};$
\item[$(vi)$] there are a vertex $v_i\in V_i$ and a vertex $v_{i+1}\in V_{i+1}$ such that $v_i,v_{i+1}\in E_{i'};$
\item[$(vii)$] there are a vertex $v_i\in V_i$ and a SuperVertex $V'_{i+1} \in V_{i+1}$ such that $v_i,V'_{i+1}\in E_{i'};$
\item[$(viii)$] there are a SuperVertex $V'_i\in V_i$ and a vertex $v_{i+1}\in V_{i+1}$ such that $V'_i,v_{i+1}\in E_{i'};$
\item[$(ix)$] there are a SuperVertex $V'_i\in V_i$ and a SuperVertex $V'_{i+1} \in V_{i+1}$ such that $V'_i,V'_{i+1}\in E_{i'}.$
\end{itemize}
\end{definition}
\begin{definition}(Characterization of the Neutrosophic neutrosophic SuperHyperPath s).\\
Assume a neutrosophic SuperHyperGraph (NSHG) $S$
is an ordered pair $S=(V,E).$ A neutrosophic neutrosophic SuperHyperPath (NSHP) from neutrosophic SuperHyperVertex (NSHV) $V_1$ to neutrosophic SuperHyperVertex (NSHV) $V_s$ is sequence of neutrosophic SuperHyperVertices (NSHV) and neutrosophic SuperHyperEdges (NSHE)
$$V_1,E_1,V_2,E_2,V_3,\ldots,V_{s-1},E_{s-1},V_s,$$
could be characterized as follow-up items.
\begin{itemize}
\item[$(i)$] If for all $V_i,E_{j'},$ $|V_i|=1,~|E_{j'}|=2,$ then NSHP is called \textbf{path};
\item[$(ii)$] if for all $E_{j'},$ $|E_{j'}|=2,$ and there's $V_i,$ $|V_i|\geq1,$ then NSHP is called \textbf{SuperPath};
\item[$(iii)$] if for all $V_i,E_{j'},$ $|V_i|=1,~|E_{j'}|\geq2,$ then NSHP is called \textbf{HyperPath};
\item[$(iv)$] if there are $V_i,E_{j'},$ $|V_i|\geq1,|E_{j'}|\geq2,$ then NSHP is called \textbf{neutrosophic SuperHyperPath }.
\end{itemize}
\end{definition}
\begin{definition}((neutrosophic) SuperHyperMatching).\\
Assume a SuperHyperGraph. Then
\begin{itemize}
\item[$(i)$]
a \textbf{neutrosophic SuperHyperMatching} $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the maximum cardinality of a SuperHyperSet $S$ of high cardinality SuperHyperEdges such that there's no SuperHyperVertex not to in a SuperHyperEdge and there's no SuperHyperEdge to have a SuperHyperVertex in a SuperHyperEdge;
\item[$(ii)$]
a \textbf{neutrosophic SuperHyperMatching} $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of high neutrosophic cardinality neutrosophic SuperHyperEdges such that there's no neutrosophic SuperHyperVertex not to in a neutrosophic SuperHyperEdge and there's no neutrosophic SuperHyperEdge to have a neutrosophic SuperHyperVertex in a neutrosophic SuperHyperEdge;
\item[$(iii)$]
a \textbf{neutrosophic SuperHyperMatching SuperHyperPolynomial} $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the neutrosophic SuperHyperPolynomial contains the coefficients defined as the number of the maximum cardinality of a SuperHyperSet $S$ of high cardinality SuperHyperEdges such that there's no SuperHyperVertex not to in a SuperHyperEdge and there's no SuperHyperEdge to have a SuperHyperVertex in a SuperHyperEdge and the power is corresponded to its coefficient;
\item[$(iv)$]
a \textbf{neutrosophic SuperHyperMatching SuperHyperPolynomial} $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the neutrosophic SuperHyperPolynomial contains the neutrosophic coefficients defined as the neutrosophic number of the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of high neutrosophic cardinality neutrosophic SuperHyperEdges such that there's no neutrosophic SuperHyperVertex not to in a neutrosophic SuperHyperEdge and there's no neutrosophic SuperHyperEdge to have a neutrosophic SuperHyperVertex in a neutrosophic SuperHyperEdge and the neutrosophic power is neutrosophicly corresponded to its neutrosophic coefficient;
\item[$(v)$]
a \textbf{neutrosophic R-SuperHyperMatching} $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the maximum cardinality of a SuperHyperSet $S$ of high cardinality SuperHyperVertices such that there's no SuperHyperVertex not to in a SuperHyperEdge and there's no SuperHyperEdge to have a SuperHyperVertex in a SuperHyperEdge;
\item[$(vi)$]
a \textbf{neutrosophic R-SuperHyperMatching} $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of high neutrosophic cardinality neutrosophic SuperHyperVertices such that there's no neutrosophic SuperHyperVertex not to in a neutrosophic SuperHyperEdge and there's no neutrosophic SuperHyperEdge to have a neutrosophic SuperHyperVertex in a neutrosophic SuperHyperEdge;
\item[$(vii)$]
a \textbf{neutrosophic R-SuperHyperMatching SuperHyperPolynomial} $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the neutrosophic SuperHyperPolynomial contains the coefficients defined as the number of the maximum cardinality of a SuperHyperSet $S$ of high cardinality SuperHyperVertices such that there's no SuperHyperVertex not to in a SuperHyperEdge and there's no SuperHyperEdge to have a SuperHyperVertex in a SuperHyperEdge and the power is corresponded to its coefficient;
\item[$(viii)$]
a \textbf{neutrosophic R-SuperHyperMatching SuperHyperPolynomial} $\mathcal{C}(NSHG)$ for a neutrosophic SuperHyperGraph $NSHG:(V,E)$ is the neutrosophic SuperHyperPolynomial contains the neutrosophic coefficients defined as the neutrosophic number of the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of high neutrosophic cardinality neutrosophic SuperHyperVertices such that there's no neutrosophic SuperHyperVertex not to in a neutrosophic SuperHyperEdge and there's no neutrosophic SuperHyperEdge to have a neutrosophic SuperHyperVertex in a neutrosophic SuperHyperEdge and the neutrosophic power is neutrosophicly corresponded to its neutrosophic coefficient.
\end{itemize}
\end{definition}
\begin{definition}((neutrosophic)$\delta-$SuperHyperMatching).\\
Assume a SuperHyperGraph. Then
\begin{itemize}
\item[$(i)$] an \textbf{$\delta-$SuperHyperMatching} is a \underline{maximal} of SuperHyperVertices with a \underline{maximum} cardinality such that either of the following expressions hold for the (neutrosophic) cardinalities of SuperHyperNeighbors of $s\in S:$
\begin{eqnarray}
&&|S\cap N(s)| > |S\cap (V\setminus N(s))|+\delta; \label{119EQN1}
\\&& |S\cap N(s)| < |S\cap (V\setminus N(s))|+\delta. \label{119EQN2}
\end{eqnarray}
The Expression \eqref{119EQN1}, holds if $S$ is an \textbf{$\delta-$SuperHyperOffensive}. And the Expression \eqref{119EQN2}, holds if $S$ is an \textbf{$\delta-$SuperHyperDefensive};
\item[$(ii)$] a \textbf{neutrosophic $\delta-$SuperHyperMatching} is a \underline{maximal} neutrosophic of SuperHyperVertices with \underline{maximum} neutrosophic cardinality such that either of the following expressions hold for the neutrosophic cardinalities of SuperHyperNeighbors of $s\in S:$
\begin{eqnarray}
&&|S\cap N(s)|_{neutrosophic} > |S\cap (V\setminus N(s))|_{neutrosophic}+\delta; \label{119EQN3}
\\&& |S\cap N(s)|_{neutrosophic} < |S\cap (V\setminus N(s))|_{neutrosophic}+\delta. \label{119EQN4}
\end{eqnarray}
The Expression \eqref{119EQN3}, holds if $S$ is a \textbf{neutrosophic $\delta-$SuperHyperOffensive}. And the Expression \eqref{119EQN4}, holds if $S$ is a \textbf{neutrosophic $\delta-$SuperHyperDefensive}.
\end{itemize}
\end{definition}
For the sake of having a neutrosophic SuperHyperMatching, there's a need to ``\textbf{redefine}'' the notion of ``neutrosophic SuperHyperGraph''. The SuperHyperVertices and the SuperHyperEdges are assigned by the labels from the letters of the alphabets. In this procedure, there's the usage of the position of labels to assign to the values.
\begin{definition}\label{119DEF1}
Assume a neutrosophic SuperHyperGraph. It's redefined \textbf{neutrosophic SuperHyperGraph} if the Table \eqref{119TBL3} holds.
\begin{table}
\centering
\caption{The Values of Vertices, SuperVertices, Edges, HyperEdges, and SuperHyperEdges Belong to The Neutrosophic SuperHyperGraph Mentioned in the Definition \eqref{119DEF1}}
\begin{tabular}[t]{c|c}
\hline
The Values of The Vertices & The Number of Position in Alphabet\\
\hline
The Values of The SuperVertices&The maximum Values of Its Vertices\\
\hline
The Values of The Edges&The maximum Values of Its Vertices\\
\hline
The Values of The HyperEdges&The maximum Values of Its Vertices\\
\hline
The Values of The SuperHyperEdges&The maximum Values of Its Endpoints \\
\hline
\end{tabular}
\label{119TBL3}
\end{table}
\end{definition}
It's useful to define a ``neutrosophic'' version of SuperHyperClasses. Since there's more ways to get neutrosophic type-results to make a neutrosophic more understandable.
\begin{definition}\label{119DEF2}
Assume a neutrosophic SuperHyperGraph. There are some \textbf{neutrosophic SuperHyperClasses} if the Table \eqref{119TBL4} holds. Thus neutrosophic SuperHyperPath , SuperHyperCycle, SuperHyperStar, SuperHyperBipartite, SuperHyperMultiPartite, and SuperHyperWheel, are
\textbf{neutrosophic neutrosophic SuperHyperPath }, \textbf{neutrosophic SuperHyperCycle}, \textbf{neutrosophic SuperHyperStar}, \textbf{neutrosophic SuperHyperBipartite}, \textbf{neutrosophic SuperHyperMultiPartite}, and \textbf{neutrosophic SuperHyperWheel} if the Table \eqref{119TBL4} holds.
\begin{table}
\centering
\caption{The Values of Vertices, SuperVertices, Edges, HyperEdges, and SuperHyperEdges Belong to The Neutrosophic SuperHyperGraph, Mentioned in the Definition \eqref{119DEF2}}
\begin{tabular}[t]{c|c}
\hline
The Values of The Vertices & The Number of Position in Alphabet\\
\hline
The Values of The SuperVertices&The maximum Values of Its Vertices\\
\hline
The Values of The Edges&The maximum Values of Its Vertices\\
\hline
The Values of The HyperEdges&The maximum Values of Its Vertices\\
\hline
The Values of The SuperHyperEdges&The maximum Values of Its Endpoints \\
\hline
\end{tabular}
\label{119TBL4}
\end{table}
\end{definition}
It's useful to define a ``neutrosophic'' version of a SuperHyperMatching. Since there's more ways to get type-results to make a SuperHyperMatching more understandable.
\\
For the sake of having a neutrosophic SuperHyperMatching, there's a need to ``\textbf{redefine}'' the notion of `` ''. The SuperHyperVertices and the SuperHyperEdges are assigned by the labels from the letters of the alphabets. In this procedure, there's the usage of the position of labels to assign to the values.
\begin{definition}\label{119DEF1}
Assume a SuperHyperMatching. It's redefined a \textbf{neutrosophic SuperHyperMatching} if the Table \eqref{119TBL1} holds. \begin{table}
\centering
\caption{The Values of Vertices, SuperVertices, Edges, HyperEdges, and SuperHyperEdges Belong to The Neutrosophic SuperHyperGraph Mentioned in the Definition \eqref{119DEF1}}
\begin{tabular}[t]{c|c}
\hline
The Values of The Vertices & The Number of Position in Alphabet\\
\hline
The Values of The SuperVertices&The maximum Values of Its Vertices\\
\hline
The Values of The Edges&The maximum Values of Its Vertices\\
\hline
The Values of The HyperEdges&The maximum Values of Its Vertices\\
\hline
The Values of The SuperHyperEdges&The maximum Values of Its Endpoints \\
\hline
\end{tabular}
\label{119TBL1}
\end{table}
\end{definition}
\section{neutrosophic SuperHyperMatching}
The SuperHyperNotion, namely, SuperHyperMatching, is up. Thus the non-obvious neutrosophic SuperHyperMatching, $S$ is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: $S$ is the neutrosophic SuperHyperSet, not: $S$ does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
$S$ in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, a neutrosophic free-triangle SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets, are $S.$ A connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ as Linearly-over-packed SuperHyperModel is featured on the Figures.
\begin{example}\label{119EXM1}
Assume the SuperHyperGraphs in the Figures \eqref{119NSHG1}, \eqref{119NSHG2}, \eqref{119NSHG3}, \eqref{119NSHG4}, \eqref{119NSHG5}, \eqref{119NSHG6}, \eqref{119NSHG7}, \eqref{119NSHG8}, \eqref{119NSHG9}, \eqref{119NSHG10}, \eqref{119NSHG11}, \eqref{119NSHG12}, \eqref{119NSHG13}, \eqref{119NSHG14}, \eqref{119NSHG15}, \eqref{119NSHG16}, \eqref{119NSHG17}, \eqref{119NSHG18}, \eqref{119NSHG19}, and \eqref{119NSHG20}.
\begin{itemize}
\item On the Figure \eqref{119NSHG1}, the neutrosophic SuperHyperNotion, namely, neutrosophic SuperHyperMatching, is up. $E_1$ and $E_3$ are some empty neutrosophic
SuperHyperEdges but $E_2$ is a loop neutrosophic SuperHyperEdge and $E_4$ is a neutrosophic SuperHyperEdge. Thus in the terms of neutrosophic SuperHyperNeighbor, there's only one neutrosophic SuperHyperEdge, namely, $E_4.$ The neutrosophic SuperHyperVertex, $V_3$ is neutrosophic isolated means that there's no neutrosophic SuperHyperEdge has it as a neutrosophic endpoint. Thus the neutrosophic SuperHyperVertex, $V_3,$ \underline{\textbf{is}} excluded in every given neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*} Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
\item On the Figure \eqref{119NSHG2}, the SuperHyperNotion, namely, SuperHyperMatching, is up. $E_1$ and $E_3$ SuperHyperMatching are some empty SuperHyperEdges but $E_2$ is a loop SuperHyperEdge and $E_4$ is a SuperHyperEdge. Thus in the terms of SuperHyperNeighbor, there's only one SuperHyperEdge, namely, $E_4.$ The SuperHyperVertex, $V_3$ is isolated means that there's no SuperHyperEdge has it as an endpoint. Thus the neutrosophic SuperHyperVertex, $V_3,$ \underline{\textbf{is}} excluded in every given neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*} Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
\item On the Figure \eqref{119NSHG3}, the SuperHyperNotion, namely, SuperHyperMatching, is up. $E_1,E_2$ and $E_3$ are some empty SuperHyperEdges but $E_4$ is a SuperHyperEdge. Thus in the terms of SuperHyperNeighbor, there's only one SuperHyperEdge, namely, $E_4.$ \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*} Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^3~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
\item On the Figure \eqref{119NSHG4}, the SuperHyperNotion, namely, a SuperHyperMatching, is up. There's no empty SuperHyperEdge but $E_3$ are a loop SuperHyperEdge on $\{F\},$ and there are some SuperHyperEdges, namely, $E_1$ on $\{H,V_1,V_3\},$ alongside $E_2$ on $\{O,H,V_4,V_3\}$ and $E_4,E_5$ on $\{N,V_1,V_2,V_3,F\}.$ \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*} \underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)=\{E_4,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=\{E_5,E_2\}~\text{is an neutrosophic SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=2z^2~\text{is an neutrosophic SuperHyperMatching SuperHyperPolynomial.}
\\&&
\mathcal{C}(NSHG)=\{V_1,V_2,V_3,V_4\}~\text{is an neutrosophic R-SuperHyperMatching.}
\\&&
\mathcal{C}(NSHG)=z^4~{\small\text{is an neutrosophic R-SuperHyperMatching SuperHyperPolynomial.}}
\end{eqnarray*}
\item On the Figure \eqref{119NSHG5}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{are} only \underline{\textbf{same}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{same}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
Doesn't have less than same SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}\underline{\textbf{Is}} the obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are only less than same neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
Thus the obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, is: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, is:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching}}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}}=4z^1.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching}}=\{V_1,V_2,V_3,V_4,V_5\}.
\\&&
\mathcal{C}(NSHG)_{\text{neutrosophic Quasi-R-SuperHyperMatching SuperHyperPolynomial}}=2z^5.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ is mentioned as the SuperHyperModel $ESHG:(V,E)$ in the Figure \eqref{119NSHG5}.
\item On the Figure \eqref{119NSHG6}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*} \underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=5z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
\item On the Figure \eqref{119NSHG7}, the SuperHyperNotion, namely, SuperHyperMatching, is up.
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*} \underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=2z^7+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=3z^{14}.
\end{eqnarray*}
\item On the Figure \eqref{119NSHG8}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ of dense SuperHyperModel as the Figure \eqref{119NSHG8}.
\item On the Figure \eqref{119NSHG9}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*} \underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=12}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=3z^{11}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{22}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{22}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ of highly-embedding-connected SuperHyperModel as the Figure \eqref{119NSHG9}.
\item On the Figure \eqref{119NSHG10}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=15}^{17}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=+z^{3}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{14}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{14}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ of dense SuperHyperModel as the Figure \eqref{119NSHG10}.
\item On the Figure \eqref{119NSHG11}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\item On the Figure \eqref{119NSHG12}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_i\}_{i=2}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^5.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^{10}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^{10}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\item On the Figure \eqref{119NSHG13}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_1,E_3\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_6,E_7,E_8\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3+z^2.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=2z^6.
\end{eqnarray*} In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\item On the Figure \eqref{119NSHG14}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_1\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_2\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^2.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's noted that this neutrosophic SuperHyperGraph $ESHG:(V,E)$ is an neutrosophic graph $G:(V,E)$ thus the notions in both settings are coincided.
\item On the Figure \eqref{119NSHG15}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching}=\{V_i\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-SuperHyperMatching SuperHyperPolynomial}=z^6.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ as Linearly-Connected SuperHyperModel On the Figure \eqref{119NSHG15}.
\item On the Figure \eqref{119NSHG16}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\item On the Figure \eqref{119NSHG17}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{15}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{15}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ as Linearly-over-packed SuperHyperModel is featured On the Figure \eqref{119NSHG17}.
\item On the Figure \eqref{119NSHG18}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^3.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\item
On the Figure \eqref{119NSHG19}, the SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i-1}\}_{i=1}^{6}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_{2i}\}_{i=1}^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=2z^{12}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\item On the Figure \eqref{119NSHG20}, the SuperHyperNotion, namely, SuperHyperMatching, is up. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}=\{E_6\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}=z^6.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\end{itemize}
\end{example}
\begin{figure}
\includegraphics[width=100mm]{119NSHG1.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG1}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG2.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG2}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG3.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG3}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG4.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG4}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG5.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG5}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG6.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG6}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG7.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG7}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG8.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG8}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG9.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG9}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG10.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG10}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG11.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG11}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG12.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG12}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG13.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG13}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG14.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG14}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG15.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG15}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG16.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG16}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG17.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG17}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG18.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG18}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG19.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG19}
\end{figure}
\begin{figure}
\includegraphics[width=100mm]{119NSHG20.png}
\caption{The SuperHyperGraphs Associated to the Notions of SuperHyperMatching in the Example \eqref{119EXM1} }
\label{119NSHG20}
\end{figure}
\begin{proposition}
Assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\end{proposition}
\begin{proof}
Assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ The SuperHyperSet of the SuperHyperVertices $V\setminus V\setminus \{z\}$ isn't a quasi-R-SuperHyperMatching since neither amount of neutrosophic SuperHyperEdges nor amount of SuperHyperVertices where amount refers to the neutrosophic number of SuperHyperVertices(-/SuperHyperEdges) more than one to form any kind of SuperHyperEdges or any number of SuperHyperEdges. Let us consider the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
This neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices has the eligibilities to propose property such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices but the maximum neutrosophic cardinality indicates that these neutrosophic type-SuperHyperSets couldn't give us the neutrosophic lower bound in the term of neutrosophic sharpness. In other words, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices implies at least on-quasi-triangle style is up but sometimes the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices is free-quasi-triangle and it doesn't make a contradiction to the supposition on the connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Thus the minimum case never happens in the generality of the connected loopless neutrosophic SuperHyperGraphs. Thus if we assume in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a quasi-R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a quasi-R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Then we've lost some connected loopless neutrosophic SuperHyperClasses of the connected loopless neutrosophic SuperHyperGraphs titled free-triangle, on-triangle, and their quasi-types but the SuperHyperStable is only up in this quasi-R-SuperHyperMatching. It's the contradiction to that fact on the generality. There are some counterexamples to deny this statement. One of them comes from the setting of the graph titled path and cycle as the counterexamples-classes or reversely direction star as the examples-classes, are well-known classes in that setting and they could be considered as the examples-classes and counterexamples-classes for the tight bound of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Let $V\setminus V\setminus \{z\}$ in mind. There's no necessity on the SuperHyperEdge since we need at least two SuperHyperVertices to form a SuperHyperEdge. It doesn't withdraw the principles of the main definition since there's no condition to be satisfied but the condition is on the existence of the SuperHyperEdge instead of acting on the SuperHyperVertices. In other words, if there's a SuperHyperEdge, then the neutrosophic SuperHyperSet has the necessary condition for the intended definition to be applied. Thus the $V\setminus V\setminus \{z\}$ is withdrawn not by the conditions of the main definition but by the necessity of the pre-condition on the usage of the main definition.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\end{proof}
\begin{proposition}
Assume a simple neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then the neutrosophic number of R-SuperHyperMatching has, the least cardinality, the lower sharp bound for cardinality, is the neutrosophic cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
If there's a R-SuperHyperMatching with the least cardinality, the lower sharp bound for cardinality.
\end{proposition}
\begin{proof}
The neutrosophic structure of the neutrosophic R-SuperHyperMatching decorates the neutrosophic SuperHyperVertices don't have received any neutrosophic connections so as this neutrosophic style implies different versions of neutrosophic SuperHyperEdges with the maximum neutrosophic cardinality in the terms of neutrosophic SuperHyperVertices are spotlight. The lower neutrosophic bound is to have the maximum neutrosophic groups of neutrosophic SuperHyperVertices have perfect neutrosophic connections inside each of SuperHyperEdges and the outside of this neutrosophic SuperHyperSet doesn't matter but regarding the connectedness of the used neutrosophic SuperHyperGraph arising from its neutrosophic properties taken from the fact that it's simple. If there's no more than one neutrosophic SuperHyperVertex in the targeted neutrosophic SuperHyperSet, then there's no neutrosophic connection. Furthermore, the neutrosophic existence of one neutrosophic SuperHyperVertex has no neutrosophic effect to talk about the neutrosophic R-SuperHyperMatching. Since at least two neutrosophic SuperHyperVertices involve to make a title in the neutrosophic background of the neutrosophic SuperHyperGraph. The neutrosophic SuperHyperGraph is obvious if it has no neutrosophic SuperHyperEdge but at least two neutrosophic SuperHyperVertices make the neutrosophic version of neutrosophic SuperHyperEdge. Thus in the neutrosophic setting of non-obvious neutrosophic SuperHyperGraph, there are at least one neutrosophic SuperHyperEdge. It's necessary to mention that the word ``Simple'' is used as neutrosophic adjective for the initial neutrosophic SuperHyperGraph, induces there's no neutrosophic appearance of the loop neutrosophic version of the neutrosophic SuperHyperEdge and this neutrosophic SuperHyperGraph is said to be loopless. The neutrosophic adjective ``loop'' on the basic neutrosophic framework engages one neutrosophic SuperHyperVertex but it never happens in this neutrosophic setting. With these neutrosophic bases, on a neutrosophic SuperHyperGraph, there's at least one neutrosophic SuperHyperEdge thus there's at least a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality of a neutrosophic SuperHyperEdge. Thus, a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality at least a neutrosophic SuperHyperEdge. Assume a neutrosophic SuperHyperSet $V\setminus V\setminus \{z\}.$ This neutrosophic SuperHyperSet isn't a neutrosophic R-SuperHyperMatching since either the neutrosophic SuperHyperGraph is an obvious neutrosophic SuperHyperModel thus it never happens since there's no neutrosophic usage of this neutrosophic framework and even more there's no neutrosophic connection inside or the neutrosophic SuperHyperGraph isn't obvious and as its consequences, there's a neutrosophic contradiction with the term ``neutrosophic R-SuperHyperMatching'' since the maximum neutrosophic cardinality never happens for this neutrosophic style of the neutrosophic SuperHyperSet and beyond that there's no neutrosophic connection inside as mentioned in first neutrosophic case in the forms of drawback for this selected neutrosophic SuperHyperSet. Let
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Comes up. This neutrosophic case implies having the neutrosophic style of on-quasi-triangle neutrosophic style on the every neutrosophic elements of this neutrosophic SuperHyperSet. Precisely, the neutrosophic R-SuperHyperMatching is the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that some neutrosophic amount of the neutrosophic SuperHyperVertices are on-quasi-triangle neutrosophic style. The neutrosophic cardinality of the v SuperHypeSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Is the maximum in comparison to the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But the lower neutrosophic bound is up. Thus the minimum neutrosophic cardinality of the maximum neutrosophic cardinality ends up the neutrosophic discussion. The first neutrosophic term refers to the neutrosophic setting of the neutrosophic SuperHyperGraph but this key point is enough since there's a neutrosophic SuperHyperClass of a neutrosophic SuperHyperGraph has no on-quasi-triangle neutrosophic style amid some amount of its neutrosophic SuperHyperVertices. This neutrosophic setting of the neutrosophic SuperHyperModel proposes a neutrosophic SuperHyperSet has only some amount neutrosophic SuperHyperVertices from one neutrosophic SuperHyperEdge such that there's no neutrosophic amount of neutrosophic SuperHyperEdges more than one involving these some amount of these neutrosophic SuperHyperVertices. The neutrosophic cardinality of this neutrosophic SuperHyperSet is the maximum and the neutrosophic case is occurred in the minimum neutrosophic situation. To sum them up, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Has the maximum neutrosophic cardinality such that
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Contains some neutrosophic SuperHyperVertices such that there's distinct-covers-order-amount neutrosophic SuperHyperEdges for amount of neutrosophic SuperHyperVertices taken from the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
It means that the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a neutrosophic R-SuperHyperMatching for the neutrosophic SuperHyperGraph as used neutrosophic background in the neutrosophic terms of worst neutrosophic case and the common theme of the lower neutrosophic bound occurred in the specific neutrosophic SuperHyperClasses of the neutrosophic SuperHyperGraphs which are neutrosophic free-quasi-triangle.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a simple neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then the neutrosophic number of R-SuperHyperMatching has, the least cardinality, the lower sharp bound for cardinality, is the neutrosophic cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
If there's a R-SuperHyperMatching with the least cardinality, the lower sharp bound for cardinality.
\end{proof}
\begin{proposition}
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\end{proposition}
\begin{proof}
Assume a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic number of the neutrosophic SuperHyperVertices. Then every neutrosophic SuperHyperVertex has at least no neutrosophic SuperHyperEdge with others in common. Thus those neutrosophic SuperHyperVertices have the eligibles to be contained in a neutrosophic R-SuperHyperMatching. Those neutrosophic SuperHyperVertices are potentially included in a neutrosophic style-R-SuperHyperMatching. Formally, consider
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
Are the neutrosophic SuperHyperVertices of a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z.$$ where the $\sim$ isn't an equivalence relation but only the symmetric relation on the neutrosophic SuperHyperVertices of the neutrosophic SuperHyperGraph. The formal definition is as follows. $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z$$ if and only if $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices and there's only and only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ between the neutrosophic SuperHyperVertices $Z_i$ and $Z_j.$ The other definition for the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ in the terms of neutrosophic R-SuperHyperMatching is
$$\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}.$$
This definition coincides with the definition of the neutrosophic R-SuperHyperMatching but with slightly differences in the maximum neutrosophic cardinality amid those neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperVertices. Thus the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$\max_z|\{Z_1,Z_2,\ldots,Z_z~|~Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}|_{\text{neutrosophic cardinality}},$$
and
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is formalized with mathematical literatures on the neutrosophic R-SuperHyperMatching. Let $Z_i\overset E\sim Z_j,$ be defined as $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices belong to the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus,
$$E=\{Z_1,Z_2,\ldots,Z_z~|~Z_i\overset E\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}.$$
Or
$$\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But with the slightly differences,
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
\{Z_1,Z_2,\ldots,Z_z~|~\forall i\neq j,~ i,j=1,2,\ldots,z,~\exists E_x,~Z_i\overset{E_x}\sim Z_j,\}.
\end{eqnarray*}
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.
\end{eqnarray*}
Thus $E\in E_{ESHG:(V,E)}$ is a neutrosophic quasi-R-SuperHyperMatching where $E\in E_{ESHG:(V,E)}$ is fixed that means $E_x=E\in E_{ESHG:(V,E)}.$ for all neutrosophic intended SuperHyperVertices but in a neutrosophic SuperHyperMatching, $E_x=E\in E_{ESHG:(V,E)}$ could be different and it's not unique. To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\end{proof}
\begin{proposition}
Assume a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\end{proposition}
\begin{proof}
The obvious SuperHyperGraph has no neutrosophic SuperHyperEdges. But the non-obvious neutrosophic SuperHyperModel is up. The quasi-SuperHyperModel addresses some issues about the neutrosophic optimal SuperHyperObject. It specially delivers some remarks on the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that there's distinct amount of neutrosophic SuperHyperEdges for distinct amount of neutrosophic SuperHyperVertices up to all taken from that neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices but this neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices is either has the maximum neutrosophic SuperHyperCardinality or it doesn't have maximum neutrosophic SuperHyperCardinality. In a non-obvious SuperHyperModel, there's at least one neutrosophic SuperHyperEdge containing at least all neutrosophic SuperHyperVertices. Thus it forms a neutrosophic quasi-R-SuperHyperMatching where the neutrosophic completion of the neutrosophic incidence is up in that. Thus it's, literarily, a neutrosophic embedded R-SuperHyperMatching. The SuperHyperNotions of embedded SuperHyperSet and quasi-SuperHyperSet coincide. In the original setting, these types of SuperHyperSets only don't satisfy on the maximum SuperHyperCardinality. Thus the embedded setting is elected such that those SuperHyperSets have the maximum neutrosophic SuperHyperCardinality and they're neutrosophic SuperHyperOptimal. The less than two distinct types of neutrosophic SuperHyperVertices are included in the minimum neutrosophic style of the embedded neutrosophic R-SuperHyperMatching. The interior types of the neutrosophic SuperHyperVertices are deciders. Since the neutrosophic number of SuperHyperNeighbors are only affected by the interior neutrosophic SuperHyperVertices. The common connections, more precise and more formal, the perfect unique connections inside the neutrosophic SuperHyperSet for any distinct types of neutrosophic SuperHyperVertices pose the neutrosophic R-SuperHyperMatching. Thus neutrosophic exterior SuperHyperVertices could be used only in one neutrosophic SuperHyperEdge and in neutrosophic SuperHyperRelation with the interior neutrosophic SuperHyperVertices in that neutrosophic SuperHyperEdge. In the embedded neutrosophic SuperHyperMatching, there's the usage of exterior neutrosophic SuperHyperVertices since they've more connections inside more than outside. Thus the title ``exterior'' is more relevant than the title ``interior''. One neutrosophic SuperHyperVertex has no connection, inside. Thus, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices with one SuperHyperElement has been ignored in the exploring to lead on the optimal case implying the neutrosophic R-SuperHyperMatching. The neutrosophic R-SuperHyperMatching with the exclusion of the exclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge and with other terms, the neutrosophic R-SuperHyperMatching with the inclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge, is a neutrosophic quasi-R-SuperHyperMatching. To sum them up, in a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\end{proof}
\begin{proposition}
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\end{proposition}
\begin{proof}
The main definition of the neutrosophic R-SuperHyperMatching has two titles. a neutrosophic quasi-R-SuperHyperMatching and its corresponded quasi-maximum neutrosophic R-SuperHyperCardinality are two titles in the terms of quasi-R-styles. For any neutrosophic number, there's a neutrosophic quasi-R-SuperHyperMatching with that quasi-maximum neutrosophic SuperHyperCardinality in the terms of the embedded neutrosophic SuperHyperGraph. If there's an embedded neutrosophic SuperHyperGraph, then the neutrosophic quasi-SuperHyperNotions lead us to take the collection of all the neutrosophic quasi-R-SuperHyperMatchings for all neutrosophic numbers less than its neutrosophic corresponded maximum number. The essence of the neutrosophic SuperHyperMatching ends up but this essence starts up in the terms of the neutrosophic quasi-R-SuperHyperMatching, again and more in the operations of collecting all the neutrosophic quasi-R-SuperHyperMatchings acted on the all possible used formations of the neutrosophic SuperHyperGraph to achieve one neutrosophic number. This neutrosophic number is considered as the equivalence class for all corresponded quasi-R-SuperHyperMatchings. Let $z_{\text{neutrosophic Number}},S_{\text{neutrosophic SuperHyperSet}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperSet and a neutrosophic SuperHyperMatching. Then
\begin{eqnarray*}
&&[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
As its consequences, the formal definition of the neutrosophic SuperHyperMatching is re-formalized and redefined as follows.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
To get more precise perceptions, the follow-up expressions propose another formal technical definition for the neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
In more concise and more convenient ways, the modified definition for the neutrosophic SuperHyperMatching poses the upcoming expressions.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
To translate the statement to this mathematical literature, the formulae will be revised.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
And then,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
To get more visions in the closer look-up, there's an overall overlook.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Now, the extension of these types of approaches is up. Since the new term, ``neutrosophic SuperHyperNeighborhood'', could be redefined as the collection of the neutrosophic SuperHyperVertices such that any amount of its neutrosophic SuperHyperVertices are incident to a neutrosophic SuperHyperEdge. It's, literarily, another name for ``neutrosophic Quasi-SuperHyperMatching'' but, precisely, it's the generalization of ``neutrosophic Quasi-SuperHyperMatching'' since ``neutrosophic Quasi-SuperHyperMatching'' happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and background but ``neutrosophic SuperHyperNeighborhood'' may not happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and preliminarily background since there are some ambiguities about the neutrosophic SuperHyperCardinality arise from it. To get orderly keywords, the terms, ``neutrosophic SuperHyperNeighborhood'', ``neutrosophic Quasi-SuperHyperMatching'', and ``neutrosophic SuperHyperMatching'' are up.
\\
Thus, let $z_{\text{neutrosophic Number}},N_{\text{neutrosophic SuperHyperNeighborhood}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperNeighborhood and a neutrosophic SuperHyperMatching and the new terms are up.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
And with go back to initial structure,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\end{proof}
\begin{proposition}\label{119PRP}
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\end{proposition}
\begin{proof}
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Let a neutrosophic SuperHyperEdge $ESHE: E\in E_{ESHG:(V,E)}$ has some neutrosophic SuperHyperVertices $r.$ Consider all neutrosophic numbers of those neutrosophic SuperHyperVertices from that neutrosophic SuperHyperEdge excluding excluding more than $r$ distinct neutrosophic SuperHyperVertices, exclude to any given neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices. Consider there's a neutrosophic R-SuperHyperMatching with the least cardinality, the lower sharp neutrosophic bound for neutrosophic cardinality. Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $ V_{ESHE}\setminus \{z\}$ is a neutrosophic SuperHyperSet $S$ of the neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely but it isn't a neutrosophic R-SuperHyperMatching. Since it doesn't have \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some SuperHyperVertices uniquely. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE}\cup \{z\}$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices but it isn't a neutrosophic R-SuperHyperMatching. Since it \textbf{\underline{doesn't do}} the neutrosophic procedure such that such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely [there are at least one neutrosophic SuperHyperVertex outside implying there's, sometimes in the connected neutrosophic SuperHyperGraph $ESHG:(V,E),$ a neutrosophic SuperHyperVertex, titled its neutrosophic SuperHyperNeighbor, to that neutrosophic SuperHyperVertex in the neutrosophic SuperHyperSet $S$ so as $S$ doesn't do ``the neutrosophic procedure''.]. There's only \textbf{\underline{one}} neutrosophic SuperHyperVertex \textbf{\underline{outside}} the intended neutrosophic SuperHyperSet, $V_{ESHE}\cup \{z\},$ in the terms of neutrosophic SuperHyperNeighborhood. Thus the obvious neutrosophic R-SuperHyperMatching, $V_{ESHE}$ is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching, $V_{ESHE},$ \textbf{\underline{is}} a neutrosophic SuperHyperSet, $V_{ESHE},$ \textbf{\underline{includes}} only \textbf{\underline{all}} neutrosophic SuperHyperVertices does forms any kind of neutrosophic pairs are titled \underline{neutrosophic SuperHyperNeighbors} in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE},$ is the \textbf{\underline{maximum neutrosophic SuperHyperCardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices \textbf{\underline{such that}} there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely. Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\end{proof}
\begin{remark}
The words `` neutrosophic SuperHyperMatching'' and ``neutrosophic SuperHyperDominating'' both refer to the maximum neutrosophic type-style. In other words, they refer to the maximum neutrosophic SuperHyperNumber and the neutrosophic SuperHyperSet with the maximum neutrosophic SuperHyperCardinality.
\end{remark}
\begin{proposition}
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Consider a neutrosophic SuperHyperDominating. Then a neutrosophic SuperHyperMatching has the members poses only one neutrosophic representative in a neutrosophic quasi-SuperHyperDominating.
\end{proposition}
\begin{proof}
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Consider a neutrosophic SuperHyperDominating. By applying the Proposition \eqref{119PRP}, the neutrosophic results are up. Thus on a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Consider a neutrosophic SuperHyperDominating. Then a neutrosophic SuperHyperMatching has the members poses only one neutrosophic representative in a neutrosophic quasi-SuperHyperDominating.
\end{proof}
\section{Results on neutrosophic SuperHyperClasses}
The previous neutrosophic approaches apply on the upcoming neutrosophic results on neutrosophic SuperHyperClasses.
\begin{proposition}
Assume a connected neutrosophic SuperHyperPath $ESHP:(V,E).$ Then a neutrosophic quasi-R-SuperHyperMatching-style with the maximum neutrosophic SuperHyperCardinality is an neutrosophic SuperHyperSet of the interior neutrosophic SuperHyperVertices.
\end{proposition}
\begin{proposition}
Assume a connected neutrosophic SuperHyperPath $ESHP:(V,E).$ Then a neutrosophic quasi-R-SuperHyperMatching is a neutrosophic SuperHyperSet of the interior neutrosophic SuperHyperVertices with only no neutrosophic exceptions in the form of interior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdges not excluding only any interior neutrosophic SuperHyperVertices from the neutrosophic unique SuperHyperEdges. a neutrosophic quasi-R-SuperHyperMatching has the neutrosophic number of all the interior neutrosophic SuperHyperVertices. Also,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
\end{proposition}
\begin{proof}
Assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ The SuperHyperSet of the SuperHyperVertices $V\setminus V\setminus \{z\}$ isn't a quasi-R-SuperHyperMatching since neither amount of neutrosophic SuperHyperEdges nor amount of SuperHyperVertices where amount refers to the neutrosophic number of SuperHyperVertices(-/SuperHyperEdges) more than one to form any kind of SuperHyperEdges or any number of SuperHyperEdges. Let us consider the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
This neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices has the eligibilities to propose property such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices but the maximum neutrosophic cardinality indicates that these neutrosophic type-SuperHyperSets couldn't give us the neutrosophic lower bound in the term of neutrosophic sharpness. In other words, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices implies at least on-quasi-triangle style is up but sometimes the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices is free-quasi-triangle and it doesn't make a contradiction to the supposition on the connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Thus the minimum case never happens in the generality of the connected loopless neutrosophic SuperHyperGraphs. Thus if we assume in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a quasi-R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a quasi-R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Then we've lost some connected loopless neutrosophic SuperHyperClasses of the connected loopless neutrosophic SuperHyperGraphs titled free-triangle, on-triangle, and their quasi-types but the SuperHyperStable is only up in this quasi-R-SuperHyperMatching. It's the contradiction to that fact on the generality. There are some counterexamples to deny this statement. One of them comes from the setting of the graph titled path and cycle as the counterexamples-classes or reversely direction star as the examples-classes, are well-known classes in that setting and they could be considered as the examples-classes and counterexamples-classes for the tight bound of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Let $V\setminus V\setminus \{z\}$ in mind. There's no necessity on the SuperHyperEdge since we need at least two SuperHyperVertices to form a SuperHyperEdge. It doesn't withdraw the principles of the main definition since there's no condition to be satisfied but the condition is on the existence of the SuperHyperEdge instead of acting on the SuperHyperVertices. In other words, if there's a SuperHyperEdge, then the neutrosophic SuperHyperSet has the necessary condition for the intended definition to be applied. Thus the $V\setminus V\setminus \{z\}$ is withdrawn not by the conditions of the main definition but by the necessity of the pre-condition on the usage of the main definition.
\\
The neutrosophic structure of the neutrosophic R-SuperHyperMatching decorates the neutrosophic SuperHyperVertices don't have received any neutrosophic connections so as this neutrosophic style implies different versions of neutrosophic SuperHyperEdges with the maximum neutrosophic cardinality in the terms of neutrosophic SuperHyperVertices are spotlight. The lower neutrosophic bound is to have the maximum neutrosophic groups of neutrosophic SuperHyperVertices have perfect neutrosophic connections inside each of SuperHyperEdges and the outside of this neutrosophic SuperHyperSet doesn't matter but regarding the connectedness of the used neutrosophic SuperHyperGraph arising from its neutrosophic properties taken from the fact that it's simple. If there's no more than one neutrosophic SuperHyperVertex in the targeted neutrosophic SuperHyperSet, then there's no neutrosophic connection. Furthermore, the neutrosophic existence of one neutrosophic SuperHyperVertex has no neutrosophic effect to talk about the neutrosophic R-SuperHyperMatching. Since at least two neutrosophic SuperHyperVertices involve to make a title in the neutrosophic background of the neutrosophic SuperHyperGraph. The neutrosophic SuperHyperGraph is obvious if it has no neutrosophic SuperHyperEdge but at least two neutrosophic SuperHyperVertices make the neutrosophic version of neutrosophic SuperHyperEdge. Thus in the neutrosophic setting of non-obvious neutrosophic SuperHyperGraph, there are at least one neutrosophic SuperHyperEdge. It's necessary to mention that the word ``Simple'' is used as neutrosophic adjective for the initial neutrosophic SuperHyperGraph, induces there's no neutrosophic appearance of the loop neutrosophic version of the neutrosophic SuperHyperEdge and this neutrosophic SuperHyperGraph is said to be loopless. The neutrosophic adjective ``loop'' on the basic neutrosophic framework engages one neutrosophic SuperHyperVertex but it never happens in this neutrosophic setting. With these neutrosophic bases, on a neutrosophic SuperHyperGraph, there's at least one neutrosophic SuperHyperEdge thus there's at least a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality of a neutrosophic SuperHyperEdge. Thus, a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality at least a neutrosophic SuperHyperEdge. Assume a neutrosophic SuperHyperSet $V\setminus V\setminus \{z\}.$ This neutrosophic SuperHyperSet isn't a neutrosophic R-SuperHyperMatching since either the neutrosophic SuperHyperGraph is an obvious neutrosophic SuperHyperModel thus it never happens since there's no neutrosophic usage of this neutrosophic framework and even more there's no neutrosophic connection inside or the neutrosophic SuperHyperGraph isn't obvious and as its consequences, there's a neutrosophic contradiction with the term ``neutrosophic R-SuperHyperMatching'' since the maximum neutrosophic cardinality never happens for this neutrosophic style of the neutrosophic SuperHyperSet and beyond that there's no neutrosophic connection inside as mentioned in first neutrosophic case in the forms of drawback for this selected neutrosophic SuperHyperSet. Let
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Comes up. This neutrosophic case implies having the neutrosophic style of on-quasi-triangle neutrosophic style on the every neutrosophic elements of this neutrosophic SuperHyperSet. Precisely, the neutrosophic R-SuperHyperMatching is the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that some neutrosophic amount of the neutrosophic SuperHyperVertices are on-quasi-triangle neutrosophic style. The neutrosophic cardinality of the v SuperHypeSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Is the maximum in comparison to the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But the lower neutrosophic bound is up. Thus the minimum neutrosophic cardinality of the maximum neutrosophic cardinality ends up the neutrosophic discussion. The first neutrosophic term refers to the neutrosophic setting of the neutrosophic SuperHyperGraph but this key point is enough since there's a neutrosophic SuperHyperClass of a neutrosophic SuperHyperGraph has no on-quasi-triangle neutrosophic style amid some amount of its neutrosophic SuperHyperVertices. This neutrosophic setting of the neutrosophic SuperHyperModel proposes a neutrosophic SuperHyperSet has only some amount neutrosophic SuperHyperVertices from one neutrosophic SuperHyperEdge such that there's no neutrosophic amount of neutrosophic SuperHyperEdges more than one involving these some amount of these neutrosophic SuperHyperVertices. The neutrosophic cardinality of this neutrosophic SuperHyperSet is the maximum and the neutrosophic case is occurred in the minimum neutrosophic situation. To sum them up, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Has the maximum neutrosophic cardinality such that
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Contains some neutrosophic SuperHyperVertices such that there's distinct-covers-order-amount neutrosophic SuperHyperEdges for amount of neutrosophic SuperHyperVertices taken from the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
It means that the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a neutrosophic R-SuperHyperMatching for the neutrosophic SuperHyperGraph as used neutrosophic background in the neutrosophic terms of worst neutrosophic case and the common theme of the lower neutrosophic bound occurred in the specific neutrosophic SuperHyperClasses of the neutrosophic SuperHyperGraphs which are neutrosophic free-quasi-triangle.
\\
Assume a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic number of the neutrosophic SuperHyperVertices. Then every neutrosophic SuperHyperVertex has at least no neutrosophic SuperHyperEdge with others in common. Thus those neutrosophic SuperHyperVertices have the eligibles to be contained in a neutrosophic R-SuperHyperMatching. Those neutrosophic SuperHyperVertices are potentially included in a neutrosophic style-R-SuperHyperMatching. Formally, consider
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
Are the neutrosophic SuperHyperVertices of a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z.$$ where the $\sim$ isn't an equivalence relation but only the symmetric relation on the neutrosophic SuperHyperVertices of the neutrosophic SuperHyperGraph. The formal definition is as follows. $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z$$ if and only if $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices and there's only and only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ between the neutrosophic SuperHyperVertices $Z_i$ and $Z_j.$ The other definition for the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ in the terms of neutrosophic R-SuperHyperMatching is
$$\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}.$$
This definition coincides with the definition of the neutrosophic R-SuperHyperMatching but with slightly differences in the maximum neutrosophic cardinality amid those neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperVertices. Thus the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$\max_z|\{Z_1,Z_2,\ldots,Z_z~|~Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}|_{\text{neutrosophic cardinality}},$$
and
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is formalized with mathematical literatures on the neutrosophic R-SuperHyperMatching. Let $Z_i\overset E\sim Z_j,$ be defined as $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices belong to the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus,
$$E=\{Z_1,Z_2,\ldots,Z_z~|~Z_i\overset E\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}.$$
Or
$$\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But with the slightly differences,
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
\{Z_1,Z_2,\ldots,Z_z~|~\forall i\neq j,~ i,j=1,2,\ldots,z,~\exists E_x,~Z_i\overset{E_x}\sim Z_j,\}.
\end{eqnarray*}
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.
\end{eqnarray*}
Thus $E\in E_{ESHG:(V,E)}$ is a neutrosophic quasi-R-SuperHyperMatching where $E\in E_{ESHG:(V,E)}$ is fixed that means $E_x=E\in E_{ESHG:(V,E)}.$ for all neutrosophic intended SuperHyperVertices but in a neutrosophic SuperHyperMatching, $E_x=E\in E_{ESHG:(V,E)}$ could be different and it's not unique. To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\\
The obvious SuperHyperGraph has no neutrosophic SuperHyperEdges. But the non-obvious neutrosophic SuperHyperModel is up. The quasi-SuperHyperModel addresses some issues about the neutrosophic optimal SuperHyperObject. It specially delivers some remarks on the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that there's distinct amount of neutrosophic SuperHyperEdges for distinct amount of neutrosophic SuperHyperVertices up to all taken from that neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices but this neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices is either has the maximum neutrosophic SuperHyperCardinality or it doesn't have maximum neutrosophic SuperHyperCardinality. In a non-obvious SuperHyperModel, there's at least one neutrosophic SuperHyperEdge containing at least all neutrosophic SuperHyperVertices. Thus it forms a neutrosophic quasi-R-SuperHyperMatching where the neutrosophic completion of the neutrosophic incidence is up in that. Thus it's, literarily, a neutrosophic embedded R-SuperHyperMatching. The SuperHyperNotions of embedded SuperHyperSet and quasi-SuperHyperSet coincide. In the original setting, these types of SuperHyperSets only don't satisfy on the maximum SuperHyperCardinality. Thus the embedded setting is elected such that those SuperHyperSets have the maximum neutrosophic SuperHyperCardinality and they're neutrosophic SuperHyperOptimal. The less than two distinct types of neutrosophic SuperHyperVertices are included in the minimum neutrosophic style of the embedded neutrosophic R-SuperHyperMatching. The interior types of the neutrosophic SuperHyperVertices are deciders. Since the neutrosophic number of SuperHyperNeighbors are only affected by the interior neutrosophic SuperHyperVertices. The common connections, more precise and more formal, the perfect unique connections inside the neutrosophic SuperHyperSet for any distinct types of neutrosophic SuperHyperVertices pose the neutrosophic R-SuperHyperMatching. Thus neutrosophic exterior SuperHyperVertices could be used only in one neutrosophic SuperHyperEdge and in neutrosophic SuperHyperRelation with the interior neutrosophic SuperHyperVertices in that neutrosophic SuperHyperEdge. In the embedded neutrosophic SuperHyperMatching, there's the usage of exterior neutrosophic SuperHyperVertices since they've more connections inside more than outside. Thus the title ``exterior'' is more relevant than the title ``interior''. One neutrosophic SuperHyperVertex has no connection, inside. Thus, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices with one SuperHyperElement has been ignored in the exploring to lead on the optimal case implying the neutrosophic R-SuperHyperMatching. The neutrosophic R-SuperHyperMatching with the exclusion of the exclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge and with other terms, the neutrosophic R-SuperHyperMatching with the inclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge, is a neutrosophic quasi-R-SuperHyperMatching. To sum them up, in a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\\
The main definition of the neutrosophic R-SuperHyperMatching has two titles. a neutrosophic quasi-R-SuperHyperMatching and its corresponded quasi-maximum neutrosophic R-SuperHyperCardinality are two titles in the terms of quasi-R-styles. For any neutrosophic number, there's a neutrosophic quasi-R-SuperHyperMatching with that quasi-maximum neutrosophic SuperHyperCardinality in the terms of the embedded neutrosophic SuperHyperGraph. If there's an embedded neutrosophic SuperHyperGraph, then the neutrosophic quasi-SuperHyperNotions lead us to take the collection of all the neutrosophic quasi-R-SuperHyperMatchings for all neutrosophic numbers less than its neutrosophic corresponded maximum number. The essence of the neutrosophic SuperHyperMatching ends up but this essence starts up in the terms of the neutrosophic quasi-R-SuperHyperMatching, again and more in the operations of collecting all the neutrosophic quasi-R-SuperHyperMatchings acted on the all possible used formations of the neutrosophic SuperHyperGraph to achieve one neutrosophic number. This neutrosophic number is considered as the equivalence class for all corresponded quasi-R-SuperHyperMatchings. Let $z_{\text{neutrosophic Number}},S_{\text{neutrosophic SuperHyperSet}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperSet and a neutrosophic SuperHyperMatching. Then
\begin{eqnarray*}
&&[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
As its consequences, the formal definition of the neutrosophic SuperHyperMatching is re-formalized and redefined as follows.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
To get more precise perceptions, the follow-up expressions propose another formal technical definition for the neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
In more concise and more convenient ways, the modified definition for the neutrosophic SuperHyperMatching poses the upcoming expressions.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
To translate the statement to this mathematical literature, the formulae will be revised.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
And then,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
To get more visions in the closer look-up, there's an overall overlook.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Now, the extension of these types of approaches is up. Since the new term, ``neutrosophic SuperHyperNeighborhood'', could be redefined as the collection of the neutrosophic SuperHyperVertices such that any amount of its neutrosophic SuperHyperVertices are incident to a neutrosophic SuperHyperEdge. It's, literarily, another name for ``neutrosophic Quasi-SuperHyperMatching'' but, precisely, it's the generalization of ``neutrosophic Quasi-SuperHyperMatching'' since ``neutrosophic Quasi-SuperHyperMatching'' happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and background but ``neutrosophic SuperHyperNeighborhood'' may not happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and preliminarily background since there are some ambiguities about the neutrosophic SuperHyperCardinality arise from it. To get orderly keywords, the terms, ``neutrosophic SuperHyperNeighborhood'', ``neutrosophic Quasi-SuperHyperMatching'', and ``neutrosophic SuperHyperMatching'' are up.
\\
Thus, let $z_{\text{neutrosophic Number}},N_{\text{neutrosophic SuperHyperNeighborhood}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperNeighborhood and a neutrosophic SuperHyperMatching and the new terms are up.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
And with go back to initial structure,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Let a neutrosophic SuperHyperEdge $ESHE: E\in E_{ESHG:(V,E)}$ has some neutrosophic SuperHyperVertices $r.$ Consider all neutrosophic numbers of those neutrosophic SuperHyperVertices from that neutrosophic SuperHyperEdge excluding excluding more than $r$ distinct neutrosophic SuperHyperVertices, exclude to any given neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices. Consider there's a neutrosophic R-SuperHyperMatching with the least cardinality, the lower sharp neutrosophic bound for neutrosophic cardinality. Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $ V_{ESHE}\setminus \{z\}$ is a neutrosophic SuperHyperSet $S$ of the neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely but it isn't a neutrosophic R-SuperHyperMatching. Since it doesn't have \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some SuperHyperVertices uniquely. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE}\cup \{z\}$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices but it isn't a neutrosophic R-SuperHyperMatching. Since it \textbf{\underline{doesn't do}} the neutrosophic procedure such that such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely [there are at least one neutrosophic SuperHyperVertex outside implying there's, sometimes in the connected neutrosophic SuperHyperGraph $ESHG:(V,E),$ a neutrosophic SuperHyperVertex, titled its neutrosophic SuperHyperNeighbor, to that neutrosophic SuperHyperVertex in the neutrosophic SuperHyperSet $S$ so as $S$ doesn't do ``the neutrosophic procedure''.]. There's only \textbf{\underline{one}} neutrosophic SuperHyperVertex \textbf{\underline{outside}} the intended neutrosophic SuperHyperSet, $V_{ESHE}\cup \{z\},$ in the terms of neutrosophic SuperHyperNeighborhood. Thus the obvious neutrosophic R-SuperHyperMatching, $V_{ESHE}$ is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching, $V_{ESHE},$ \textbf{\underline{is}} a neutrosophic SuperHyperSet, $V_{ESHE},$ \textbf{\underline{includes}} only \textbf{\underline{all}} neutrosophic SuperHyperVertices does forms any kind of neutrosophic pairs are titled \underline{neutrosophic SuperHyperNeighbors} in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE},$ is the \textbf{\underline{maximum neutrosophic SuperHyperCardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices \textbf{\underline{such that}} there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely. Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\\
The SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\end{proof}
\begin{example}\label{119EXM18a}
In the Figure \eqref{119NSHG18a}, the connected neutrosophic SuperHyperPath $ESHP:(V,E),$ is highlighted and featured. The neutrosophic SuperHyperSet, in the neutrosophic SuperHyperModel \eqref{119NSHG18a}, is the SuperHyperMatching.
\begin{figure}
\includegraphics[width=100mm]{119NSHG18.png}
\caption{a neutrosophic SuperHyperPath Associated to the Notions of neutrosophic SuperHyperMatching in the Example \eqref{119EXM18a}}
\label{119NSHG18a}
\end{figure}
\end{example}
\begin{proposition}
Assume a connected neutrosophic SuperHyperCycle $ESHC:(V,E).$ Then a neutrosophic quasi-R-SuperHyperMatching is a neutrosophic SuperHyperSet of the interior neutrosophic SuperHyperVertices with only no neutrosophic exceptions on the form of interior neutrosophic SuperHyperVertices from the same neutrosophic SuperHyperNeighborhoods not excluding any neutrosophic SuperHyperVertex. a neutrosophic quasi-R-SuperHyperMatching has the neutrosophic half number of all the neutrosophic SuperHyperEdges in the terms of the maximum neutrosophic cardinality. Also,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
\end{proposition}
\begin{proof}
Assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ The SuperHyperSet of the SuperHyperVertices $V\setminus V\setminus \{z\}$ isn't a quasi-R-SuperHyperMatching since neither amount of neutrosophic SuperHyperEdges nor amount of SuperHyperVertices where amount refers to the neutrosophic number of SuperHyperVertices(-/SuperHyperEdges) more than one to form any kind of SuperHyperEdges or any number of SuperHyperEdges. Let us consider the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
This neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices has the eligibilities to propose property such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices but the maximum neutrosophic cardinality indicates that these neutrosophic type-SuperHyperSets couldn't give us the neutrosophic lower bound in the term of neutrosophic sharpness. In other words, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices implies at least on-quasi-triangle style is up but sometimes the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices is free-quasi-triangle and it doesn't make a contradiction to the supposition on the connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Thus the minimum case never happens in the generality of the connected loopless neutrosophic SuperHyperGraphs. Thus if we assume in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a quasi-R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a quasi-R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Then we've lost some connected loopless neutrosophic SuperHyperClasses of the connected loopless neutrosophic SuperHyperGraphs titled free-triangle, on-triangle, and their quasi-types but the SuperHyperStable is only up in this quasi-R-SuperHyperMatching. It's the contradiction to that fact on the generality. There are some counterexamples to deny this statement. One of them comes from the setting of the graph titled path and cycle as the counterexamples-classes or reversely direction star as the examples-classes, are well-known classes in that setting and they could be considered as the examples-classes and counterexamples-classes for the tight bound of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Let $V\setminus V\setminus \{z\}$ in mind. There's no necessity on the SuperHyperEdge since we need at least two SuperHyperVertices to form a SuperHyperEdge. It doesn't withdraw the principles of the main definition since there's no condition to be satisfied but the condition is on the existence of the SuperHyperEdge instead of acting on the SuperHyperVertices. In other words, if there's a SuperHyperEdge, then the neutrosophic SuperHyperSet has the necessary condition for the intended definition to be applied. Thus the $V\setminus V\setminus \{z\}$ is withdrawn not by the conditions of the main definition but by the necessity of the pre-condition on the usage of the main definition.
\\
The neutrosophic structure of the neutrosophic R-SuperHyperMatching decorates the neutrosophic SuperHyperVertices don't have received any neutrosophic connections so as this neutrosophic style implies different versions of neutrosophic SuperHyperEdges with the maximum neutrosophic cardinality in the terms of neutrosophic SuperHyperVertices are spotlight. The lower neutrosophic bound is to have the maximum neutrosophic groups of neutrosophic SuperHyperVertices have perfect neutrosophic connections inside each of SuperHyperEdges and the outside of this neutrosophic SuperHyperSet doesn't matter but regarding the connectedness of the used neutrosophic SuperHyperGraph arising from its neutrosophic properties taken from the fact that it's simple. If there's no more than one neutrosophic SuperHyperVertex in the targeted neutrosophic SuperHyperSet, then there's no neutrosophic connection. Furthermore, the neutrosophic existence of one neutrosophic SuperHyperVertex has no neutrosophic effect to talk about the neutrosophic R-SuperHyperMatching. Since at least two neutrosophic SuperHyperVertices involve to make a title in the neutrosophic background of the neutrosophic SuperHyperGraph. The neutrosophic SuperHyperGraph is obvious if it has no neutrosophic SuperHyperEdge but at least two neutrosophic SuperHyperVertices make the neutrosophic version of neutrosophic SuperHyperEdge. Thus in the neutrosophic setting of non-obvious neutrosophic SuperHyperGraph, there are at least one neutrosophic SuperHyperEdge. It's necessary to mention that the word ``Simple'' is used as neutrosophic adjective for the initial neutrosophic SuperHyperGraph, induces there's no neutrosophic appearance of the loop neutrosophic version of the neutrosophic SuperHyperEdge and this neutrosophic SuperHyperGraph is said to be loopless. The neutrosophic adjective ``loop'' on the basic neutrosophic framework engages one neutrosophic SuperHyperVertex but it never happens in this neutrosophic setting. With these neutrosophic bases, on a neutrosophic SuperHyperGraph, there's at least one neutrosophic SuperHyperEdge thus there's at least a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality of a neutrosophic SuperHyperEdge. Thus, a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality at least a neutrosophic SuperHyperEdge. Assume a neutrosophic SuperHyperSet $V\setminus V\setminus \{z\}.$ This neutrosophic SuperHyperSet isn't a neutrosophic R-SuperHyperMatching since either the neutrosophic SuperHyperGraph is an obvious neutrosophic SuperHyperModel thus it never happens since there's no neutrosophic usage of this neutrosophic framework and even more there's no neutrosophic connection inside or the neutrosophic SuperHyperGraph isn't obvious and as its consequences, there's a neutrosophic contradiction with the term ``neutrosophic R-SuperHyperMatching'' since the maximum neutrosophic cardinality never happens for this neutrosophic style of the neutrosophic SuperHyperSet and beyond that there's no neutrosophic connection inside as mentioned in first neutrosophic case in the forms of drawback for this selected neutrosophic SuperHyperSet. Let
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Comes up. This neutrosophic case implies having the neutrosophic style of on-quasi-triangle neutrosophic style on the every neutrosophic elements of this neutrosophic SuperHyperSet. Precisely, the neutrosophic R-SuperHyperMatching is the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that some neutrosophic amount of the neutrosophic SuperHyperVertices are on-quasi-triangle neutrosophic style. The neutrosophic cardinality of the v SuperHypeSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Is the maximum in comparison to the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But the lower neutrosophic bound is up. Thus the minimum neutrosophic cardinality of the maximum neutrosophic cardinality ends up the neutrosophic discussion. The first neutrosophic term refers to the neutrosophic setting of the neutrosophic SuperHyperGraph but this key point is enough since there's a neutrosophic SuperHyperClass of a neutrosophic SuperHyperGraph has no on-quasi-triangle neutrosophic style amid some amount of its neutrosophic SuperHyperVertices. This neutrosophic setting of the neutrosophic SuperHyperModel proposes a neutrosophic SuperHyperSet has only some amount neutrosophic SuperHyperVertices from one neutrosophic SuperHyperEdge such that there's no neutrosophic amount of neutrosophic SuperHyperEdges more than one involving these some amount of these neutrosophic SuperHyperVertices. The neutrosophic cardinality of this neutrosophic SuperHyperSet is the maximum and the neutrosophic case is occurred in the minimum neutrosophic situation. To sum them up, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Has the maximum neutrosophic cardinality such that
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Contains some neutrosophic SuperHyperVertices such that there's distinct-covers-order-amount neutrosophic SuperHyperEdges for amount of neutrosophic SuperHyperVertices taken from the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
It means that the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a neutrosophic R-SuperHyperMatching for the neutrosophic SuperHyperGraph as used neutrosophic background in the neutrosophic terms of worst neutrosophic case and the common theme of the lower neutrosophic bound occurred in the specific neutrosophic SuperHyperClasses of the neutrosophic SuperHyperGraphs which are neutrosophic free-quasi-triangle.
\\
Assume a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic number of the neutrosophic SuperHyperVertices. Then every neutrosophic SuperHyperVertex has at least no neutrosophic SuperHyperEdge with others in common. Thus those neutrosophic SuperHyperVertices have the eligibles to be contained in a neutrosophic R-SuperHyperMatching. Those neutrosophic SuperHyperVertices are potentially included in a neutrosophic style-R-SuperHyperMatching. Formally, consider
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
Are the neutrosophic SuperHyperVertices of a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z.$$ where the $\sim$ isn't an equivalence relation but only the symmetric relation on the neutrosophic SuperHyperVertices of the neutrosophic SuperHyperGraph. The formal definition is as follows. $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z$$ if and only if $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices and there's only and only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ between the neutrosophic SuperHyperVertices $Z_i$ and $Z_j.$ The other definition for the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ in the terms of neutrosophic R-SuperHyperMatching is
$$\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}.$$
This definition coincides with the definition of the neutrosophic R-SuperHyperMatching but with slightly differences in the maximum neutrosophic cardinality amid those neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperVertices. Thus the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$\max_z|\{Z_1,Z_2,\ldots,Z_z~|~Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}|_{\text{neutrosophic cardinality}},$$
and
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is formalized with mathematical literatures on the neutrosophic R-SuperHyperMatching. Let $Z_i\overset E\sim Z_j,$ be defined as $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices belong to the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus,
$$E=\{Z_1,Z_2,\ldots,Z_z~|~Z_i\overset E\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}.$$
Or
$$\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But with the slightly differences,
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
\{Z_1,Z_2,\ldots,Z_z~|~\forall i\neq j,~ i,j=1,2,\ldots,z,~\exists E_x,~Z_i\overset{E_x}\sim Z_j,\}.
\end{eqnarray*}
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.
\end{eqnarray*}
Thus $E\in E_{ESHG:(V,E)}$ is a neutrosophic quasi-R-SuperHyperMatching where $E\in E_{ESHG:(V,E)}$ is fixed that means $E_x=E\in E_{ESHG:(V,E)}.$ for all neutrosophic intended SuperHyperVertices but in a neutrosophic SuperHyperMatching, $E_x=E\in E_{ESHG:(V,E)}$ could be different and it's not unique. To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\\
The obvious SuperHyperGraph has no neutrosophic SuperHyperEdges. But the non-obvious neutrosophic SuperHyperModel is up. The quasi-SuperHyperModel addresses some issues about the neutrosophic optimal SuperHyperObject. It specially delivers some remarks on the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that there's distinct amount of neutrosophic SuperHyperEdges for distinct amount of neutrosophic SuperHyperVertices up to all taken from that neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices but this neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices is either has the maximum neutrosophic SuperHyperCardinality or it doesn't have maximum neutrosophic SuperHyperCardinality. In a non-obvious SuperHyperModel, there's at least one neutrosophic SuperHyperEdge containing at least all neutrosophic SuperHyperVertices. Thus it forms a neutrosophic quasi-R-SuperHyperMatching where the neutrosophic completion of the neutrosophic incidence is up in that. Thus it's, literarily, a neutrosophic embedded R-SuperHyperMatching. The SuperHyperNotions of embedded SuperHyperSet and quasi-SuperHyperSet coincide. In the original setting, these types of SuperHyperSets only don't satisfy on the maximum SuperHyperCardinality. Thus the embedded setting is elected such that those SuperHyperSets have the maximum neutrosophic SuperHyperCardinality and they're neutrosophic SuperHyperOptimal. The less than two distinct types of neutrosophic SuperHyperVertices are included in the minimum neutrosophic style of the embedded neutrosophic R-SuperHyperMatching. The interior types of the neutrosophic SuperHyperVertices are deciders. Since the neutrosophic number of SuperHyperNeighbors are only affected by the interior neutrosophic SuperHyperVertices. The common connections, more precise and more formal, the perfect unique connections inside the neutrosophic SuperHyperSet for any distinct types of neutrosophic SuperHyperVertices pose the neutrosophic R-SuperHyperMatching. Thus neutrosophic exterior SuperHyperVertices could be used only in one neutrosophic SuperHyperEdge and in neutrosophic SuperHyperRelation with the interior neutrosophic SuperHyperVertices in that neutrosophic SuperHyperEdge. In the embedded neutrosophic SuperHyperMatching, there's the usage of exterior neutrosophic SuperHyperVertices since they've more connections inside more than outside. Thus the title ``exterior'' is more relevant than the title ``interior''. One neutrosophic SuperHyperVertex has no connection, inside. Thus, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices with one SuperHyperElement has been ignored in the exploring to lead on the optimal case implying the neutrosophic R-SuperHyperMatching. The neutrosophic R-SuperHyperMatching with the exclusion of the exclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge and with other terms, the neutrosophic R-SuperHyperMatching with the inclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge, is a neutrosophic quasi-R-SuperHyperMatching. To sum them up, in a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\\
The main definition of the neutrosophic R-SuperHyperMatching has two titles. a neutrosophic quasi-R-SuperHyperMatching and its corresponded quasi-maximum neutrosophic R-SuperHyperCardinality are two titles in the terms of quasi-R-styles. For any neutrosophic number, there's a neutrosophic quasi-R-SuperHyperMatching with that quasi-maximum neutrosophic SuperHyperCardinality in the terms of the embedded neutrosophic SuperHyperGraph. If there's an embedded neutrosophic SuperHyperGraph, then the neutrosophic quasi-SuperHyperNotions lead us to take the collection of all the neutrosophic quasi-R-SuperHyperMatchings for all neutrosophic numbers less than its neutrosophic corresponded maximum number. The essence of the neutrosophic SuperHyperMatching ends up but this essence starts up in the terms of the neutrosophic quasi-R-SuperHyperMatching, again and more in the operations of collecting all the neutrosophic quasi-R-SuperHyperMatchings acted on the all possible used formations of the neutrosophic SuperHyperGraph to achieve one neutrosophic number. This neutrosophic number is considered as the equivalence class for all corresponded quasi-R-SuperHyperMatchings. Let $z_{\text{neutrosophic Number}},S_{\text{neutrosophic SuperHyperSet}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperSet and a neutrosophic SuperHyperMatching. Then
\begin{eqnarray*}
&&[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
As its consequences, the formal definition of the neutrosophic SuperHyperMatching is re-formalized and redefined as follows.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
To get more precise perceptions, the follow-up expressions propose another formal technical definition for the neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
In more concise and more convenient ways, the modified definition for the neutrosophic SuperHyperMatching poses the upcoming expressions.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
To translate the statement to this mathematical literature, the formulae will be revised.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
And then,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
To get more visions in the closer look-up, there's an overall overlook.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Now, the extension of these types of approaches is up. Since the new term, ``neutrosophic SuperHyperNeighborhood'', could be redefined as the collection of the neutrosophic SuperHyperVertices such that any amount of its neutrosophic SuperHyperVertices are incident to a neutrosophic SuperHyperEdge. It's, literarily, another name for ``neutrosophic Quasi-SuperHyperMatching'' but, precisely, it's the generalization of ``neutrosophic Quasi-SuperHyperMatching'' since ``neutrosophic Quasi-SuperHyperMatching'' happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and background but ``neutrosophic SuperHyperNeighborhood'' may not happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and preliminarily background since there are some ambiguities about the neutrosophic SuperHyperCardinality arise from it. To get orderly keywords, the terms, ``neutrosophic SuperHyperNeighborhood'', ``neutrosophic Quasi-SuperHyperMatching'', and ``neutrosophic SuperHyperMatching'' are up.
\\
Thus, let $z_{\text{neutrosophic Number}},N_{\text{neutrosophic SuperHyperNeighborhood}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperNeighborhood and a neutrosophic SuperHyperMatching and the new terms are up.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
And with go back to initial structure,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Let a neutrosophic SuperHyperEdge $ESHE: E\in E_{ESHG:(V,E)}$ has some neutrosophic SuperHyperVertices $r.$ Consider all neutrosophic numbers of those neutrosophic SuperHyperVertices from that neutrosophic SuperHyperEdge excluding excluding more than $r$ distinct neutrosophic SuperHyperVertices, exclude to any given neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices. Consider there's a neutrosophic R-SuperHyperMatching with the least cardinality, the lower sharp neutrosophic bound for neutrosophic cardinality. Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $ V_{ESHE}\setminus \{z\}$ is a neutrosophic SuperHyperSet $S$ of the neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely but it isn't a neutrosophic R-SuperHyperMatching. Since it doesn't have \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some SuperHyperVertices uniquely. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE}\cup \{z\}$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices but it isn't a neutrosophic R-SuperHyperMatching. Since it \textbf{\underline{doesn't do}} the neutrosophic procedure such that such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely [there are at least one neutrosophic SuperHyperVertex outside implying there's, sometimes in the connected neutrosophic SuperHyperGraph $ESHG:(V,E),$ a neutrosophic SuperHyperVertex, titled its neutrosophic SuperHyperNeighbor, to that neutrosophic SuperHyperVertex in the neutrosophic SuperHyperSet $S$ so as $S$ doesn't do ``the neutrosophic procedure''.]. There's only \textbf{\underline{one}} neutrosophic SuperHyperVertex \textbf{\underline{outside}} the intended neutrosophic SuperHyperSet, $V_{ESHE}\cup \{z\},$ in the terms of neutrosophic SuperHyperNeighborhood. Thus the obvious neutrosophic R-SuperHyperMatching, $V_{ESHE}$ is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching, $V_{ESHE},$ \textbf{\underline{is}} a neutrosophic SuperHyperSet, $V_{ESHE},$ \textbf{\underline{includes}} only \textbf{\underline{all}} neutrosophic SuperHyperVertices does forms any kind of neutrosophic pairs are titled \underline{neutrosophic SuperHyperNeighbors} in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE},$ is the \textbf{\underline{maximum neutrosophic SuperHyperCardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices \textbf{\underline{such that}} there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely. Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\\
The SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\end{proof}
\begin{example}\label{119EXM19a}
In the Figure \eqref{119NSHG19a}, the connected neutrosophic SuperHyperCycle $NSHC:(V,E),$ is highlighted and featured. The obtained neutrosophic SuperHyperSet, in the neutrosophic SuperHyperModel \eqref{119NSHG19a},
is the neutrosophic SuperHyperMatching.
\begin{figure}
\includegraphics[width=100mm]{119NSHG19.png}
\caption{a neutrosophic SuperHyperCycle Associated to the neutrosophic Notions of neutrosophic SuperHyperMatching in the neutrosophic Example \eqref{119EXM19a}}
\label{119NSHG19a}
\end{figure}
\end{example}
\begin{proposition}
Assume a connected neutrosophic SuperHyperStar $ESHS:(V,E).$ Then a neutrosophic quasi-R-SuperHyperMatching is a neutrosophic SuperHyperSet of the interior neutrosophic SuperHyperVertices, corresponded to a neutrosophic SuperHyperEdge. a neutrosophic quasi-R-SuperHyperMatching has the neutrosophic number of the neutrosophic cardinality of the one neutrosophic SuperHyperEdge. Also, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
\end{proposition}
\begin{proof}
Assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ The SuperHyperSet of the SuperHyperVertices $V\setminus V\setminus \{z\}$ isn't a quasi-R-SuperHyperMatching since neither amount of neutrosophic SuperHyperEdges nor amount of SuperHyperVertices where amount refers to the neutrosophic number of SuperHyperVertices(-/SuperHyperEdges) more than one to form any kind of SuperHyperEdges or any number of SuperHyperEdges. Let us consider the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
This neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices has the eligibilities to propose property such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices but the maximum neutrosophic cardinality indicates that these neutrosophic type-SuperHyperSets couldn't give us the neutrosophic lower bound in the term of neutrosophic sharpness. In other words, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices implies at least on-quasi-triangle style is up but sometimes the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices is free-quasi-triangle and it doesn't make a contradiction to the supposition on the connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Thus the minimum case never happens in the generality of the connected loopless neutrosophic SuperHyperGraphs. Thus if we assume in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a quasi-R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a quasi-R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Then we've lost some connected loopless neutrosophic SuperHyperClasses of the connected loopless neutrosophic SuperHyperGraphs titled free-triangle, on-triangle, and their quasi-types but the SuperHyperStable is only up in this quasi-R-SuperHyperMatching. It's the contradiction to that fact on the generality. There are some counterexamples to deny this statement. One of them comes from the setting of the graph titled path and cycle as the counterexamples-classes or reversely direction star as the examples-classes, are well-known classes in that setting and they could be considered as the examples-classes and counterexamples-classes for the tight bound of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Let $V\setminus V\setminus \{z\}$ in mind. There's no necessity on the SuperHyperEdge since we need at least two SuperHyperVertices to form a SuperHyperEdge. It doesn't withdraw the principles of the main definition since there's no condition to be satisfied but the condition is on the existence of the SuperHyperEdge instead of acting on the SuperHyperVertices. In other words, if there's a SuperHyperEdge, then the neutrosophic SuperHyperSet has the necessary condition for the intended definition to be applied. Thus the $V\setminus V\setminus \{z\}$ is withdrawn not by the conditions of the main definition but by the necessity of the pre-condition on the usage of the main definition.
\\
The neutrosophic structure of the neutrosophic R-SuperHyperMatching decorates the neutrosophic SuperHyperVertices don't have received any neutrosophic connections so as this neutrosophic style implies different versions of neutrosophic SuperHyperEdges with the maximum neutrosophic cardinality in the terms of neutrosophic SuperHyperVertices are spotlight. The lower neutrosophic bound is to have the maximum neutrosophic groups of neutrosophic SuperHyperVertices have perfect neutrosophic connections inside each of SuperHyperEdges and the outside of this neutrosophic SuperHyperSet doesn't matter but regarding the connectedness of the used neutrosophic SuperHyperGraph arising from its neutrosophic properties taken from the fact that it's simple. If there's no more than one neutrosophic SuperHyperVertex in the targeted neutrosophic SuperHyperSet, then there's no neutrosophic connection. Furthermore, the neutrosophic existence of one neutrosophic SuperHyperVertex has no neutrosophic effect to talk about the neutrosophic R-SuperHyperMatching. Since at least two neutrosophic SuperHyperVertices involve to make a title in the neutrosophic background of the neutrosophic SuperHyperGraph. The neutrosophic SuperHyperGraph is obvious if it has no neutrosophic SuperHyperEdge but at least two neutrosophic SuperHyperVertices make the neutrosophic version of neutrosophic SuperHyperEdge. Thus in the neutrosophic setting of non-obvious neutrosophic SuperHyperGraph, there are at least one neutrosophic SuperHyperEdge. It's necessary to mention that the word ``Simple'' is used as neutrosophic adjective for the initial neutrosophic SuperHyperGraph, induces there's no neutrosophic appearance of the loop neutrosophic version of the neutrosophic SuperHyperEdge and this neutrosophic SuperHyperGraph is said to be loopless. The neutrosophic adjective ``loop'' on the basic neutrosophic framework engages one neutrosophic SuperHyperVertex but it never happens in this neutrosophic setting. With these neutrosophic bases, on a neutrosophic SuperHyperGraph, there's at least one neutrosophic SuperHyperEdge thus there's at least a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality of a neutrosophic SuperHyperEdge. Thus, a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality at least a neutrosophic SuperHyperEdge. Assume a neutrosophic SuperHyperSet $V\setminus V\setminus \{z\}.$ This neutrosophic SuperHyperSet isn't a neutrosophic R-SuperHyperMatching since either the neutrosophic SuperHyperGraph is an obvious neutrosophic SuperHyperModel thus it never happens since there's no neutrosophic usage of this neutrosophic framework and even more there's no neutrosophic connection inside or the neutrosophic SuperHyperGraph isn't obvious and as its consequences, there's a neutrosophic contradiction with the term ``neutrosophic R-SuperHyperMatching'' since the maximum neutrosophic cardinality never happens for this neutrosophic style of the neutrosophic SuperHyperSet and beyond that there's no neutrosophic connection inside as mentioned in first neutrosophic case in the forms of drawback for this selected neutrosophic SuperHyperSet. Let
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Comes up. This neutrosophic case implies having the neutrosophic style of on-quasi-triangle neutrosophic style on the every neutrosophic elements of this neutrosophic SuperHyperSet. Precisely, the neutrosophic R-SuperHyperMatching is the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that some neutrosophic amount of the neutrosophic SuperHyperVertices are on-quasi-triangle neutrosophic style. The neutrosophic cardinality of the v SuperHypeSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Is the maximum in comparison to the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But the lower neutrosophic bound is up. Thus the minimum neutrosophic cardinality of the maximum neutrosophic cardinality ends up the neutrosophic discussion. The first neutrosophic term refers to the neutrosophic setting of the neutrosophic SuperHyperGraph but this key point is enough since there's a neutrosophic SuperHyperClass of a neutrosophic SuperHyperGraph has no on-quasi-triangle neutrosophic style amid some amount of its neutrosophic SuperHyperVertices. This neutrosophic setting of the neutrosophic SuperHyperModel proposes a neutrosophic SuperHyperSet has only some amount neutrosophic SuperHyperVertices from one neutrosophic SuperHyperEdge such that there's no neutrosophic amount of neutrosophic SuperHyperEdges more than one involving these some amount of these neutrosophic SuperHyperVertices. The neutrosophic cardinality of this neutrosophic SuperHyperSet is the maximum and the neutrosophic case is occurred in the minimum neutrosophic situation. To sum them up, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Has the maximum neutrosophic cardinality such that
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Contains some neutrosophic SuperHyperVertices such that there's distinct-covers-order-amount neutrosophic SuperHyperEdges for amount of neutrosophic SuperHyperVertices taken from the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
It means that the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a neutrosophic R-SuperHyperMatching for the neutrosophic SuperHyperGraph as used neutrosophic background in the neutrosophic terms of worst neutrosophic case and the common theme of the lower neutrosophic bound occurred in the specific neutrosophic SuperHyperClasses of the neutrosophic SuperHyperGraphs which are neutrosophic free-quasi-triangle.
\\
Assume a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic number of the neutrosophic SuperHyperVertices. Then every neutrosophic SuperHyperVertex has at least no neutrosophic SuperHyperEdge with others in common. Thus those neutrosophic SuperHyperVertices have the eligibles to be contained in a neutrosophic R-SuperHyperMatching. Those neutrosophic SuperHyperVertices are potentially included in a neutrosophic style-R-SuperHyperMatching. Formally, consider
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
Are the neutrosophic SuperHyperVertices of a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z.$$ where the $\sim$ isn't an equivalence relation but only the symmetric relation on the neutrosophic SuperHyperVertices of the neutrosophic SuperHyperGraph. The formal definition is as follows. $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z$$ if and only if $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices and there's only and only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ between the neutrosophic SuperHyperVertices $Z_i$ and $Z_j.$ The other definition for the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ in the terms of neutrosophic R-SuperHyperMatching is
$$\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}.$$
This definition coincides with the definition of the neutrosophic R-SuperHyperMatching but with slightly differences in the maximum neutrosophic cardinality amid those neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperVertices. Thus the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$\max_z|\{Z_1,Z_2,\ldots,Z_z~|~Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}|_{\text{neutrosophic cardinality}},$$
and
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is formalized with mathematical literatures on the neutrosophic R-SuperHyperMatching. Let $Z_i\overset E\sim Z_j,$ be defined as $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices belong to the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus,
$$E=\{Z_1,Z_2,\ldots,Z_z~|~Z_i\overset E\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}.$$
Or
$$\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But with the slightly differences,
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
\{Z_1,Z_2,\ldots,Z_z~|~\forall i\neq j,~ i,j=1,2,\ldots,z,~\exists E_x,~Z_i\overset{E_x}\sim Z_j,\}.
\end{eqnarray*}
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.
\end{eqnarray*}
Thus $E\in E_{ESHG:(V,E)}$ is a neutrosophic quasi-R-SuperHyperMatching where $E\in E_{ESHG:(V,E)}$ is fixed that means $E_x=E\in E_{ESHG:(V,E)}.$ for all neutrosophic intended SuperHyperVertices but in a neutrosophic SuperHyperMatching, $E_x=E\in E_{ESHG:(V,E)}$ could be different and it's not unique. To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\\
The obvious SuperHyperGraph has no neutrosophic SuperHyperEdges. But the non-obvious neutrosophic SuperHyperModel is up. The quasi-SuperHyperModel addresses some issues about the neutrosophic optimal SuperHyperObject. It specially delivers some remarks on the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that there's distinct amount of neutrosophic SuperHyperEdges for distinct amount of neutrosophic SuperHyperVertices up to all taken from that neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices but this neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices is either has the maximum neutrosophic SuperHyperCardinality or it doesn't have maximum neutrosophic SuperHyperCardinality. In a non-obvious SuperHyperModel, there's at least one neutrosophic SuperHyperEdge containing at least all neutrosophic SuperHyperVertices. Thus it forms a neutrosophic quasi-R-SuperHyperMatching where the neutrosophic completion of the neutrosophic incidence is up in that. Thus it's, literarily, a neutrosophic embedded R-SuperHyperMatching. The SuperHyperNotions of embedded SuperHyperSet and quasi-SuperHyperSet coincide. In the original setting, these types of SuperHyperSets only don't satisfy on the maximum SuperHyperCardinality. Thus the embedded setting is elected such that those SuperHyperSets have the maximum neutrosophic SuperHyperCardinality and they're neutrosophic SuperHyperOptimal. The less than two distinct types of neutrosophic SuperHyperVertices are included in the minimum neutrosophic style of the embedded neutrosophic R-SuperHyperMatching. The interior types of the neutrosophic SuperHyperVertices are deciders. Since the neutrosophic number of SuperHyperNeighbors are only affected by the interior neutrosophic SuperHyperVertices. The common connections, more precise and more formal, the perfect unique connections inside the neutrosophic SuperHyperSet for any distinct types of neutrosophic SuperHyperVertices pose the neutrosophic R-SuperHyperMatching. Thus neutrosophic exterior SuperHyperVertices could be used only in one neutrosophic SuperHyperEdge and in neutrosophic SuperHyperRelation with the interior neutrosophic SuperHyperVertices in that neutrosophic SuperHyperEdge. In the embedded neutrosophic SuperHyperMatching, there's the usage of exterior neutrosophic SuperHyperVertices since they've more connections inside more than outside. Thus the title ``exterior'' is more relevant than the title ``interior''. One neutrosophic SuperHyperVertex has no connection, inside. Thus, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices with one SuperHyperElement has been ignored in the exploring to lead on the optimal case implying the neutrosophic R-SuperHyperMatching. The neutrosophic R-SuperHyperMatching with the exclusion of the exclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge and with other terms, the neutrosophic R-SuperHyperMatching with the inclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge, is a neutrosophic quasi-R-SuperHyperMatching. To sum them up, in a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\\
The main definition of the neutrosophic R-SuperHyperMatching has two titles. a neutrosophic quasi-R-SuperHyperMatching and its corresponded quasi-maximum neutrosophic R-SuperHyperCardinality are two titles in the terms of quasi-R-styles. For any neutrosophic number, there's a neutrosophic quasi-R-SuperHyperMatching with that quasi-maximum neutrosophic SuperHyperCardinality in the terms of the embedded neutrosophic SuperHyperGraph. If there's an embedded neutrosophic SuperHyperGraph, then the neutrosophic quasi-SuperHyperNotions lead us to take the collection of all the neutrosophic quasi-R-SuperHyperMatchings for all neutrosophic numbers less than its neutrosophic corresponded maximum number. The essence of the neutrosophic SuperHyperMatching ends up but this essence starts up in the terms of the neutrosophic quasi-R-SuperHyperMatching, again and more in the operations of collecting all the neutrosophic quasi-R-SuperHyperMatchings acted on the all possible used formations of the neutrosophic SuperHyperGraph to achieve one neutrosophic number. This neutrosophic number is considered as the equivalence class for all corresponded quasi-R-SuperHyperMatchings. Let $z_{\text{neutrosophic Number}},S_{\text{neutrosophic SuperHyperSet}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperSet and a neutrosophic SuperHyperMatching. Then
\begin{eqnarray*}
&&[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
As its consequences, the formal definition of the neutrosophic SuperHyperMatching is re-formalized and redefined as follows.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
To get more precise perceptions, the follow-up expressions propose another formal technical definition for the neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
In more concise and more convenient ways, the modified definition for the neutrosophic SuperHyperMatching poses the upcoming expressions.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
To translate the statement to this mathematical literature, the formulae will be revised.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
And then,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
To get more visions in the closer look-up, there's an overall overlook.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Now, the extension of these types of approaches is up. Since the new term, ``neutrosophic SuperHyperNeighborhood'', could be redefined as the collection of the neutrosophic SuperHyperVertices such that any amount of its neutrosophic SuperHyperVertices are incident to a neutrosophic SuperHyperEdge. It's, literarily, another name for ``neutrosophic Quasi-SuperHyperMatching'' but, precisely, it's the generalization of ``neutrosophic Quasi-SuperHyperMatching'' since ``neutrosophic Quasi-SuperHyperMatching'' happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and background but ``neutrosophic SuperHyperNeighborhood'' may not happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and preliminarily background since there are some ambiguities about the neutrosophic SuperHyperCardinality arise from it. To get orderly keywords, the terms, ``neutrosophic SuperHyperNeighborhood'', ``neutrosophic Quasi-SuperHyperMatching'', and ``neutrosophic SuperHyperMatching'' are up.
\\
Thus, let $z_{\text{neutrosophic Number}},N_{\text{neutrosophic SuperHyperNeighborhood}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperNeighborhood and a neutrosophic SuperHyperMatching and the new terms are up.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
And with go back to initial structure,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Let a neutrosophic SuperHyperEdge $ESHE: E\in E_{ESHG:(V,E)}$ has some neutrosophic SuperHyperVertices $r.$ Consider all neutrosophic numbers of those neutrosophic SuperHyperVertices from that neutrosophic SuperHyperEdge excluding excluding more than $r$ distinct neutrosophic SuperHyperVertices, exclude to any given neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices. Consider there's a neutrosophic R-SuperHyperMatching with the least cardinality, the lower sharp neutrosophic bound for neutrosophic cardinality. Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $ V_{ESHE}\setminus \{z\}$ is a neutrosophic SuperHyperSet $S$ of the neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely but it isn't a neutrosophic R-SuperHyperMatching. Since it doesn't have \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some SuperHyperVertices uniquely. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE}\cup \{z\}$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices but it isn't a neutrosophic R-SuperHyperMatching. Since it \textbf{\underline{doesn't do}} the neutrosophic procedure such that such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely [there are at least one neutrosophic SuperHyperVertex outside implying there's, sometimes in the connected neutrosophic SuperHyperGraph $ESHG:(V,E),$ a neutrosophic SuperHyperVertex, titled its neutrosophic SuperHyperNeighbor, to that neutrosophic SuperHyperVertex in the neutrosophic SuperHyperSet $S$ so as $S$ doesn't do ``the neutrosophic procedure''.]. There's only \textbf{\underline{one}} neutrosophic SuperHyperVertex \textbf{\underline{outside}} the intended neutrosophic SuperHyperSet, $V_{ESHE}\cup \{z\},$ in the terms of neutrosophic SuperHyperNeighborhood. Thus the obvious neutrosophic R-SuperHyperMatching, $V_{ESHE}$ is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching, $V_{ESHE},$ \textbf{\underline{is}} a neutrosophic SuperHyperSet, $V_{ESHE},$ \textbf{\underline{includes}} only \textbf{\underline{all}} neutrosophic SuperHyperVertices does forms any kind of neutrosophic pairs are titled \underline{neutrosophic SuperHyperNeighbors} in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE},$ is the \textbf{\underline{maximum neutrosophic SuperHyperCardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices \textbf{\underline{such that}} there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely. Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\\
The SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E\in E_{ESHG:(V,E)}\}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=\sum_{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}z^{|E|_{\text{neutrosophic Cardinality}}~|~E:\in E_{ESHG:(V,E)}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t},\ldots.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=z^{s}+z^{t}+,\ldots.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\end{proof}
\begin{example}\label{119EXM20a}
In the Figure \eqref{119NSHG20a}, the connected neutrosophic SuperHyperStar $ESHS:(V,E),$ is highlighted and featured. The obtained neutrosophic SuperHyperSet, by the Algorithm in previous neutrosophic result, of the neutrosophic SuperHyperVertices of the connected neutrosophic SuperHyperStar $ESHS:(V,E),$ in the neutrosophic SuperHyperModel \eqref{119NSHG20a}, is the neutrosophic SuperHyperMatching.
\begin{figure}
\includegraphics[width=100mm]{119NSHG20.png}
\caption{a neutrosophic SuperHyperStar Associated to the neutrosophic Notions of neutrosophic SuperHyperMatching in the neutrosophic Example \eqref{119EXM20a}}
\label{119NSHG20a}
\end{figure}
\end{example}
\begin{proposition}
Assume a connected neutrosophic SuperHyperBipartite $ESHB:(V,E).$ Then a neutrosophic R-SuperHyperMatching is a neutrosophic SuperHyperSet of the interior neutrosophic SuperHyperVertices with no neutrosophic exceptions in the form of interior neutrosophic SuperHyperVertices titled neutrosophic SuperHyperNeighbors. a neutrosophic R-SuperHyperMatching has the neutrosophic maximum number of on neutrosophic cardinality of the minimum SuperHyperPart minus those have common neutrosophic SuperHyperNeighbors and not unique neutrosophic SuperHyperNeighbors. Also,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
\end{proposition}
\begin{proof}
Assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ The SuperHyperSet of the SuperHyperVertices $V\setminus V\setminus \{z\}$ isn't a quasi-R-SuperHyperMatching since neither amount of neutrosophic SuperHyperEdges nor amount of SuperHyperVertices where amount refers to the neutrosophic number of SuperHyperVertices(-/SuperHyperEdges) more than one to form any kind of SuperHyperEdges or any number of SuperHyperEdges. Let us consider the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
This neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices has the eligibilities to propose property such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices but the maximum neutrosophic cardinality indicates that these neutrosophic type-SuperHyperSets couldn't give us the neutrosophic lower bound in the term of neutrosophic sharpness. In other words, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices implies at least on-quasi-triangle style is up but sometimes the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices is free-quasi-triangle and it doesn't make a contradiction to the supposition on the connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Thus the minimum case never happens in the generality of the connected loopless neutrosophic SuperHyperGraphs. Thus if we assume in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a quasi-R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a quasi-R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Then we've lost some connected loopless neutrosophic SuperHyperClasses of the connected loopless neutrosophic SuperHyperGraphs titled free-triangle, on-triangle, and their quasi-types but the SuperHyperStable is only up in this quasi-R-SuperHyperMatching. It's the contradiction to that fact on the generality. There are some counterexamples to deny this statement. One of them comes from the setting of the graph titled path and cycle as the counterexamples-classes or reversely direction star as the examples-classes, are well-known classes in that setting and they could be considered as the examples-classes and counterexamples-classes for the tight bound of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Let $V\setminus V\setminus \{z\}$ in mind. There's no necessity on the SuperHyperEdge since we need at least two SuperHyperVertices to form a SuperHyperEdge. It doesn't withdraw the principles of the main definition since there's no condition to be satisfied but the condition is on the existence of the SuperHyperEdge instead of acting on the SuperHyperVertices. In other words, if there's a SuperHyperEdge, then the neutrosophic SuperHyperSet has the necessary condition for the intended definition to be applied. Thus the $V\setminus V\setminus \{z\}$ is withdrawn not by the conditions of the main definition but by the necessity of the pre-condition on the usage of the main definition.
\\
The neutrosophic structure of the neutrosophic R-SuperHyperMatching decorates the neutrosophic SuperHyperVertices don't have received any neutrosophic connections so as this neutrosophic style implies different versions of neutrosophic SuperHyperEdges with the maximum neutrosophic cardinality in the terms of neutrosophic SuperHyperVertices are spotlight. The lower neutrosophic bound is to have the maximum neutrosophic groups of neutrosophic SuperHyperVertices have perfect neutrosophic connections inside each of SuperHyperEdges and the outside of this neutrosophic SuperHyperSet doesn't matter but regarding the connectedness of the used neutrosophic SuperHyperGraph arising from its neutrosophic properties taken from the fact that it's simple. If there's no more than one neutrosophic SuperHyperVertex in the targeted neutrosophic SuperHyperSet, then there's no neutrosophic connection. Furthermore, the neutrosophic existence of one neutrosophic SuperHyperVertex has no neutrosophic effect to talk about the neutrosophic R-SuperHyperMatching. Since at least two neutrosophic SuperHyperVertices involve to make a title in the neutrosophic background of the neutrosophic SuperHyperGraph. The neutrosophic SuperHyperGraph is obvious if it has no neutrosophic SuperHyperEdge but at least two neutrosophic SuperHyperVertices make the neutrosophic version of neutrosophic SuperHyperEdge. Thus in the neutrosophic setting of non-obvious neutrosophic SuperHyperGraph, there are at least one neutrosophic SuperHyperEdge. It's necessary to mention that the word ``Simple'' is used as neutrosophic adjective for the initial neutrosophic SuperHyperGraph, induces there's no neutrosophic appearance of the loop neutrosophic version of the neutrosophic SuperHyperEdge and this neutrosophic SuperHyperGraph is said to be loopless. The neutrosophic adjective ``loop'' on the basic neutrosophic framework engages one neutrosophic SuperHyperVertex but it never happens in this neutrosophic setting. With these neutrosophic bases, on a neutrosophic SuperHyperGraph, there's at least one neutrosophic SuperHyperEdge thus there's at least a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality of a neutrosophic SuperHyperEdge. Thus, a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality at least a neutrosophic SuperHyperEdge. Assume a neutrosophic SuperHyperSet $V\setminus V\setminus \{z\}.$ This neutrosophic SuperHyperSet isn't a neutrosophic R-SuperHyperMatching since either the neutrosophic SuperHyperGraph is an obvious neutrosophic SuperHyperModel thus it never happens since there's no neutrosophic usage of this neutrosophic framework and even more there's no neutrosophic connection inside or the neutrosophic SuperHyperGraph isn't obvious and as its consequences, there's a neutrosophic contradiction with the term ``neutrosophic R-SuperHyperMatching'' since the maximum neutrosophic cardinality never happens for this neutrosophic style of the neutrosophic SuperHyperSet and beyond that there's no neutrosophic connection inside as mentioned in first neutrosophic case in the forms of drawback for this selected neutrosophic SuperHyperSet. Let
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Comes up. This neutrosophic case implies having the neutrosophic style of on-quasi-triangle neutrosophic style on the every neutrosophic elements of this neutrosophic SuperHyperSet. Precisely, the neutrosophic R-SuperHyperMatching is the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that some neutrosophic amount of the neutrosophic SuperHyperVertices are on-quasi-triangle neutrosophic style. The neutrosophic cardinality of the v SuperHypeSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Is the maximum in comparison to the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But the lower neutrosophic bound is up. Thus the minimum neutrosophic cardinality of the maximum neutrosophic cardinality ends up the neutrosophic discussion. The first neutrosophic term refers to the neutrosophic setting of the neutrosophic SuperHyperGraph but this key point is enough since there's a neutrosophic SuperHyperClass of a neutrosophic SuperHyperGraph has no on-quasi-triangle neutrosophic style amid some amount of its neutrosophic SuperHyperVertices. This neutrosophic setting of the neutrosophic SuperHyperModel proposes a neutrosophic SuperHyperSet has only some amount neutrosophic SuperHyperVertices from one neutrosophic SuperHyperEdge such that there's no neutrosophic amount of neutrosophic SuperHyperEdges more than one involving these some amount of these neutrosophic SuperHyperVertices. The neutrosophic cardinality of this neutrosophic SuperHyperSet is the maximum and the neutrosophic case is occurred in the minimum neutrosophic situation. To sum them up, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Has the maximum neutrosophic cardinality such that
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Contains some neutrosophic SuperHyperVertices such that there's distinct-covers-order-amount neutrosophic SuperHyperEdges for amount of neutrosophic SuperHyperVertices taken from the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
It means that the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a neutrosophic R-SuperHyperMatching for the neutrosophic SuperHyperGraph as used neutrosophic background in the neutrosophic terms of worst neutrosophic case and the common theme of the lower neutrosophic bound occurred in the specific neutrosophic SuperHyperClasses of the neutrosophic SuperHyperGraphs which are neutrosophic free-quasi-triangle.
\\
Assume a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic number of the neutrosophic SuperHyperVertices. Then every neutrosophic SuperHyperVertex has at least no neutrosophic SuperHyperEdge with others in common. Thus those neutrosophic SuperHyperVertices have the eligibles to be contained in a neutrosophic R-SuperHyperMatching. Those neutrosophic SuperHyperVertices are potentially included in a neutrosophic style-R-SuperHyperMatching. Formally, consider
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
Are the neutrosophic SuperHyperVertices of a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z.$$ where the $\sim$ isn't an equivalence relation but only the symmetric relation on the neutrosophic SuperHyperVertices of the neutrosophic SuperHyperGraph. The formal definition is as follows. $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z$$ if and only if $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices and there's only and only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ between the neutrosophic SuperHyperVertices $Z_i$ and $Z_j.$ The other definition for the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ in the terms of neutrosophic R-SuperHyperMatching is
$$\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}.$$
This definition coincides with the definition of the neutrosophic R-SuperHyperMatching but with slightly differences in the maximum neutrosophic cardinality amid those neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperVertices. Thus the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$\max_z|\{Z_1,Z_2,\ldots,Z_z~|~Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}|_{\text{neutrosophic cardinality}},$$
and
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is formalized with mathematical literatures on the neutrosophic R-SuperHyperMatching. Let $Z_i\overset E\sim Z_j,$ be defined as $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices belong to the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus,
$$E=\{Z_1,Z_2,\ldots,Z_z~|~Z_i\overset E\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}.$$
Or
$$\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But with the slightly differences,
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
\{Z_1,Z_2,\ldots,Z_z~|~\forall i\neq j,~ i,j=1,2,\ldots,z,~\exists E_x,~Z_i\overset{E_x}\sim Z_j,\}.
\end{eqnarray*}
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.
\end{eqnarray*}
Thus $E\in E_{ESHG:(V,E)}$ is a neutrosophic quasi-R-SuperHyperMatching where $E\in E_{ESHG:(V,E)}$ is fixed that means $E_x=E\in E_{ESHG:(V,E)}.$ for all neutrosophic intended SuperHyperVertices but in a neutrosophic SuperHyperMatching, $E_x=E\in E_{ESHG:(V,E)}$ could be different and it's not unique. To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\\
The obvious SuperHyperGraph has no neutrosophic SuperHyperEdges. But the non-obvious neutrosophic SuperHyperModel is up. The quasi-SuperHyperModel addresses some issues about the neutrosophic optimal SuperHyperObject. It specially delivers some remarks on the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that there's distinct amount of neutrosophic SuperHyperEdges for distinct amount of neutrosophic SuperHyperVertices up to all taken from that neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices but this neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices is either has the maximum neutrosophic SuperHyperCardinality or it doesn't have maximum neutrosophic SuperHyperCardinality. In a non-obvious SuperHyperModel, there's at least one neutrosophic SuperHyperEdge containing at least all neutrosophic SuperHyperVertices. Thus it forms a neutrosophic quasi-R-SuperHyperMatching where the neutrosophic completion of the neutrosophic incidence is up in that. Thus it's, literarily, a neutrosophic embedded R-SuperHyperMatching. The SuperHyperNotions of embedded SuperHyperSet and quasi-SuperHyperSet coincide. In the original setting, these types of SuperHyperSets only don't satisfy on the maximum SuperHyperCardinality. Thus the embedded setting is elected such that those SuperHyperSets have the maximum neutrosophic SuperHyperCardinality and they're neutrosophic SuperHyperOptimal. The less than two distinct types of neutrosophic SuperHyperVertices are included in the minimum neutrosophic style of the embedded neutrosophic R-SuperHyperMatching. The interior types of the neutrosophic SuperHyperVertices are deciders. Since the neutrosophic number of SuperHyperNeighbors are only affected by the interior neutrosophic SuperHyperVertices. The common connections, more precise and more formal, the perfect unique connections inside the neutrosophic SuperHyperSet for any distinct types of neutrosophic SuperHyperVertices pose the neutrosophic R-SuperHyperMatching. Thus neutrosophic exterior SuperHyperVertices could be used only in one neutrosophic SuperHyperEdge and in neutrosophic SuperHyperRelation with the interior neutrosophic SuperHyperVertices in that neutrosophic SuperHyperEdge. In the embedded neutrosophic SuperHyperMatching, there's the usage of exterior neutrosophic SuperHyperVertices since they've more connections inside more than outside. Thus the title ``exterior'' is more relevant than the title ``interior''. One neutrosophic SuperHyperVertex has no connection, inside. Thus, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices with one SuperHyperElement has been ignored in the exploring to lead on the optimal case implying the neutrosophic R-SuperHyperMatching. The neutrosophic R-SuperHyperMatching with the exclusion of the exclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge and with other terms, the neutrosophic R-SuperHyperMatching with the inclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge, is a neutrosophic quasi-R-SuperHyperMatching. To sum them up, in a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\\
The main definition of the neutrosophic R-SuperHyperMatching has two titles. a neutrosophic quasi-R-SuperHyperMatching and its corresponded quasi-maximum neutrosophic R-SuperHyperCardinality are two titles in the terms of quasi-R-styles. For any neutrosophic number, there's a neutrosophic quasi-R-SuperHyperMatching with that quasi-maximum neutrosophic SuperHyperCardinality in the terms of the embedded neutrosophic SuperHyperGraph. If there's an embedded neutrosophic SuperHyperGraph, then the neutrosophic quasi-SuperHyperNotions lead us to take the collection of all the neutrosophic quasi-R-SuperHyperMatchings for all neutrosophic numbers less than its neutrosophic corresponded maximum number. The essence of the neutrosophic SuperHyperMatching ends up but this essence starts up in the terms of the neutrosophic quasi-R-SuperHyperMatching, again and more in the operations of collecting all the neutrosophic quasi-R-SuperHyperMatchings acted on the all possible used formations of the neutrosophic SuperHyperGraph to achieve one neutrosophic number. This neutrosophic number is considered as the equivalence class for all corresponded quasi-R-SuperHyperMatchings. Let $z_{\text{neutrosophic Number}},S_{\text{neutrosophic SuperHyperSet}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperSet and a neutrosophic SuperHyperMatching. Then
\begin{eqnarray*}
&&[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
As its consequences, the formal definition of the neutrosophic SuperHyperMatching is re-formalized and redefined as follows.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
To get more precise perceptions, the follow-up expressions propose another formal technical definition for the neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
In more concise and more convenient ways, the modified definition for the neutrosophic SuperHyperMatching poses the upcoming expressions.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
To translate the statement to this mathematical literature, the formulae will be revised.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
And then,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
To get more visions in the closer look-up, there's an overall overlook.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Now, the extension of these types of approaches is up. Since the new term, ``neutrosophic SuperHyperNeighborhood'', could be redefined as the collection of the neutrosophic SuperHyperVertices such that any amount of its neutrosophic SuperHyperVertices are incident to a neutrosophic SuperHyperEdge. It's, literarily, another name for ``neutrosophic Quasi-SuperHyperMatching'' but, precisely, it's the generalization of ``neutrosophic Quasi-SuperHyperMatching'' since ``neutrosophic Quasi-SuperHyperMatching'' happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and background but ``neutrosophic SuperHyperNeighborhood'' may not happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and preliminarily background since there are some ambiguities about the neutrosophic SuperHyperCardinality arise from it. To get orderly keywords, the terms, ``neutrosophic SuperHyperNeighborhood'', ``neutrosophic Quasi-SuperHyperMatching'', and ``neutrosophic SuperHyperMatching'' are up.
\\
Thus, let $z_{\text{neutrosophic Number}},N_{\text{neutrosophic SuperHyperNeighborhood}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperNeighborhood and a neutrosophic SuperHyperMatching and the new terms are up.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
And with go back to initial structure,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Let a neutrosophic SuperHyperEdge $ESHE: E\in E_{ESHG:(V,E)}$ has some neutrosophic SuperHyperVertices $r.$ Consider all neutrosophic numbers of those neutrosophic SuperHyperVertices from that neutrosophic SuperHyperEdge excluding excluding more than $r$ distinct neutrosophic SuperHyperVertices, exclude to any given neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices. Consider there's a neutrosophic R-SuperHyperMatching with the least cardinality, the lower sharp neutrosophic bound for neutrosophic cardinality. Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $ V_{ESHE}\setminus \{z\}$ is a neutrosophic SuperHyperSet $S$ of the neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely but it isn't a neutrosophic R-SuperHyperMatching. Since it doesn't have \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some SuperHyperVertices uniquely. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE}\cup \{z\}$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices but it isn't a neutrosophic R-SuperHyperMatching. Since it \textbf{\underline{doesn't do}} the neutrosophic procedure such that such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely [there are at least one neutrosophic SuperHyperVertex outside implying there's, sometimes in the connected neutrosophic SuperHyperGraph $ESHG:(V,E),$ a neutrosophic SuperHyperVertex, titled its neutrosophic SuperHyperNeighbor, to that neutrosophic SuperHyperVertex in the neutrosophic SuperHyperSet $S$ so as $S$ doesn't do ``the neutrosophic procedure''.]. There's only \textbf{\underline{one}} neutrosophic SuperHyperVertex \textbf{\underline{outside}} the intended neutrosophic SuperHyperSet, $V_{ESHE}\cup \{z\},$ in the terms of neutrosophic SuperHyperNeighborhood. Thus the obvious neutrosophic R-SuperHyperMatching, $V_{ESHE}$ is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching, $V_{ESHE},$ \textbf{\underline{is}} a neutrosophic SuperHyperSet, $V_{ESHE},$ \textbf{\underline{includes}} only \textbf{\underline{all}} neutrosophic SuperHyperVertices does forms any kind of neutrosophic pairs are titled \underline{neutrosophic SuperHyperNeighbors} in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE},$ is the \textbf{\underline{maximum neutrosophic SuperHyperCardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices \textbf{\underline{such that}} there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely. Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\\
The SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\end{proof}
\begin{example}\label{119EXM21a}
In the neutrosophic Figure \eqref{119NSHG21a}, the connected neutrosophic SuperHyperBipartite $ESHB:(V,E),$ is neutrosophic highlighted and neutrosophic featured. The obtained neutrosophic SuperHyperSet, by the neutrosophic Algorithm in previous neutrosophic result, of the neutrosophic SuperHyperVertices of the connected neutrosophic SuperHyperBipartite $ESHB:(V,E),$ in the neutrosophic SuperHyperModel \eqref{119NSHG21a}, is the neutrosophic SuperHyperMatching.
\begin{figure}
\includegraphics[width=100mm]{119NSHG21.png}
\caption{a neutrosophic SuperHyperBipartite neutrosophic Associated to the neutrosophic Notions of neutrosophic SuperHyperMatching in the Example \eqref{119EXM21a}}
\label{119NSHG21a}
\end{figure}
\end{example}
\begin{proposition}
Assume a connected neutrosophic SuperHyperMultipartite $ESHM:(V,E).$ Then a neutrosophic R-SuperHyperMatching is a neutrosophic SuperHyperSet of the interior neutrosophic SuperHyperVertices with only no neutrosophic exception in the neutrosophic form of interior neutrosophic SuperHyperVertices from a neutrosophic SuperHyperPart and only no exception in the form of interior SuperHyperVertices from another SuperHyperPart titled ``SuperHyperNeighbors'' with neglecting and ignoring more than some of them aren't SuperHyperNeighbors to all. a neutrosophic R-SuperHyperMatching has the neutrosophic maximum number on all the neutrosophic summation on the neutrosophic cardinality of the all neutrosophic SuperHyperParts form some SuperHyperEdges minus those make neutrosophic SuperHypeNeighbors to some not all or not unique. Also,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
\end{proposition}
\begin{proof}
Assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ The SuperHyperSet of the SuperHyperVertices $V\setminus V\setminus \{z\}$ isn't a quasi-R-SuperHyperMatching since neither amount of neutrosophic SuperHyperEdges nor amount of SuperHyperVertices where amount refers to the neutrosophic number of SuperHyperVertices(-/SuperHyperEdges) more than one to form any kind of SuperHyperEdges or any number of SuperHyperEdges. Let us consider the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
This neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices has the eligibilities to propose property such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices but the maximum neutrosophic cardinality indicates that these neutrosophic type-SuperHyperSets couldn't give us the neutrosophic lower bound in the term of neutrosophic sharpness. In other words, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices implies at least on-quasi-triangle style is up but sometimes the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices is free-quasi-triangle and it doesn't make a contradiction to the supposition on the connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Thus the minimum case never happens in the generality of the connected loopless neutrosophic SuperHyperGraphs. Thus if we assume in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a quasi-R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a quasi-R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Then we've lost some connected loopless neutrosophic SuperHyperClasses of the connected loopless neutrosophic SuperHyperGraphs titled free-triangle, on-triangle, and their quasi-types but the SuperHyperStable is only up in this quasi-R-SuperHyperMatching. It's the contradiction to that fact on the generality. There are some counterexamples to deny this statement. One of them comes from the setting of the graph titled path and cycle as the counterexamples-classes or reversely direction star as the examples-classes, are well-known classes in that setting and they could be considered as the examples-classes and counterexamples-classes for the tight bound of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Let $V\setminus V\setminus \{z\}$ in mind. There's no necessity on the SuperHyperEdge since we need at least two SuperHyperVertices to form a SuperHyperEdge. It doesn't withdraw the principles of the main definition since there's no condition to be satisfied but the condition is on the existence of the SuperHyperEdge instead of acting on the SuperHyperVertices. In other words, if there's a SuperHyperEdge, then the neutrosophic SuperHyperSet has the necessary condition for the intended definition to be applied. Thus the $V\setminus V\setminus \{z\}$ is withdrawn not by the conditions of the main definition but by the necessity of the pre-condition on the usage of the main definition.
\\
The neutrosophic structure of the neutrosophic R-SuperHyperMatching decorates the neutrosophic SuperHyperVertices don't have received any neutrosophic connections so as this neutrosophic style implies different versions of neutrosophic SuperHyperEdges with the maximum neutrosophic cardinality in the terms of neutrosophic SuperHyperVertices are spotlight. The lower neutrosophic bound is to have the maximum neutrosophic groups of neutrosophic SuperHyperVertices have perfect neutrosophic connections inside each of SuperHyperEdges and the outside of this neutrosophic SuperHyperSet doesn't matter but regarding the connectedness of the used neutrosophic SuperHyperGraph arising from its neutrosophic properties taken from the fact that it's simple. If there's no more than one neutrosophic SuperHyperVertex in the targeted neutrosophic SuperHyperSet, then there's no neutrosophic connection. Furthermore, the neutrosophic existence of one neutrosophic SuperHyperVertex has no neutrosophic effect to talk about the neutrosophic R-SuperHyperMatching. Since at least two neutrosophic SuperHyperVertices involve to make a title in the neutrosophic background of the neutrosophic SuperHyperGraph. The neutrosophic SuperHyperGraph is obvious if it has no neutrosophic SuperHyperEdge but at least two neutrosophic SuperHyperVertices make the neutrosophic version of neutrosophic SuperHyperEdge. Thus in the neutrosophic setting of non-obvious neutrosophic SuperHyperGraph, there are at least one neutrosophic SuperHyperEdge. It's necessary to mention that the word ``Simple'' is used as neutrosophic adjective for the initial neutrosophic SuperHyperGraph, induces there's no neutrosophic appearance of the loop neutrosophic version of the neutrosophic SuperHyperEdge and this neutrosophic SuperHyperGraph is said to be loopless. The neutrosophic adjective ``loop'' on the basic neutrosophic framework engages one neutrosophic SuperHyperVertex but it never happens in this neutrosophic setting. With these neutrosophic bases, on a neutrosophic SuperHyperGraph, there's at least one neutrosophic SuperHyperEdge thus there's at least a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality of a neutrosophic SuperHyperEdge. Thus, a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality at least a neutrosophic SuperHyperEdge. Assume a neutrosophic SuperHyperSet $V\setminus V\setminus \{z\}.$ This neutrosophic SuperHyperSet isn't a neutrosophic R-SuperHyperMatching since either the neutrosophic SuperHyperGraph is an obvious neutrosophic SuperHyperModel thus it never happens since there's no neutrosophic usage of this neutrosophic framework and even more there's no neutrosophic connection inside or the neutrosophic SuperHyperGraph isn't obvious and as its consequences, there's a neutrosophic contradiction with the term ``neutrosophic R-SuperHyperMatching'' since the maximum neutrosophic cardinality never happens for this neutrosophic style of the neutrosophic SuperHyperSet and beyond that there's no neutrosophic connection inside as mentioned in first neutrosophic case in the forms of drawback for this selected neutrosophic SuperHyperSet. Let
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Comes up. This neutrosophic case implies having the neutrosophic style of on-quasi-triangle neutrosophic style on the every neutrosophic elements of this neutrosophic SuperHyperSet. Precisely, the neutrosophic R-SuperHyperMatching is the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that some neutrosophic amount of the neutrosophic SuperHyperVertices are on-quasi-triangle neutrosophic style. The neutrosophic cardinality of the v SuperHypeSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Is the maximum in comparison to the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But the lower neutrosophic bound is up. Thus the minimum neutrosophic cardinality of the maximum neutrosophic cardinality ends up the neutrosophic discussion. The first neutrosophic term refers to the neutrosophic setting of the neutrosophic SuperHyperGraph but this key point is enough since there's a neutrosophic SuperHyperClass of a neutrosophic SuperHyperGraph has no on-quasi-triangle neutrosophic style amid some amount of its neutrosophic SuperHyperVertices. This neutrosophic setting of the neutrosophic SuperHyperModel proposes a neutrosophic SuperHyperSet has only some amount neutrosophic SuperHyperVertices from one neutrosophic SuperHyperEdge such that there's no neutrosophic amount of neutrosophic SuperHyperEdges more than one involving these some amount of these neutrosophic SuperHyperVertices. The neutrosophic cardinality of this neutrosophic SuperHyperSet is the maximum and the neutrosophic case is occurred in the minimum neutrosophic situation. To sum them up, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Has the maximum neutrosophic cardinality such that
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Contains some neutrosophic SuperHyperVertices such that there's distinct-covers-order-amount neutrosophic SuperHyperEdges for amount of neutrosophic SuperHyperVertices taken from the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
It means that the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a neutrosophic R-SuperHyperMatching for the neutrosophic SuperHyperGraph as used neutrosophic background in the neutrosophic terms of worst neutrosophic case and the common theme of the lower neutrosophic bound occurred in the specific neutrosophic SuperHyperClasses of the neutrosophic SuperHyperGraphs which are neutrosophic free-quasi-triangle.
\\
Assume a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic number of the neutrosophic SuperHyperVertices. Then every neutrosophic SuperHyperVertex has at least no neutrosophic SuperHyperEdge with others in common. Thus those neutrosophic SuperHyperVertices have the eligibles to be contained in a neutrosophic R-SuperHyperMatching. Those neutrosophic SuperHyperVertices are potentially included in a neutrosophic style-R-SuperHyperMatching. Formally, consider
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
Are the neutrosophic SuperHyperVertices of a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z.$$ where the $\sim$ isn't an equivalence relation but only the symmetric relation on the neutrosophic SuperHyperVertices of the neutrosophic SuperHyperGraph. The formal definition is as follows. $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z$$ if and only if $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices and there's only and only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ between the neutrosophic SuperHyperVertices $Z_i$ and $Z_j.$ The other definition for the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ in the terms of neutrosophic R-SuperHyperMatching is
$$\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}.$$
This definition coincides with the definition of the neutrosophic R-SuperHyperMatching but with slightly differences in the maximum neutrosophic cardinality amid those neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperVertices. Thus the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$\max_z|\{Z_1,Z_2,\ldots,Z_z~|~Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}|_{\text{neutrosophic cardinality}},$$
and
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is formalized with mathematical literatures on the neutrosophic R-SuperHyperMatching. Let $Z_i\overset E\sim Z_j,$ be defined as $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices belong to the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus,
$$E=\{Z_1,Z_2,\ldots,Z_z~|~Z_i\overset E\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}.$$
Or
$$\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But with the slightly differences,
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
\{Z_1,Z_2,\ldots,Z_z~|~\forall i\neq j,~ i,j=1,2,\ldots,z,~\exists E_x,~Z_i\overset{E_x}\sim Z_j,\}.
\end{eqnarray*}
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.
\end{eqnarray*}
Thus $E\in E_{ESHG:(V,E)}$ is a neutrosophic quasi-R-SuperHyperMatching where $E\in E_{ESHG:(V,E)}$ is fixed that means $E_x=E\in E_{ESHG:(V,E)}.$ for all neutrosophic intended SuperHyperVertices but in a neutrosophic SuperHyperMatching, $E_x=E\in E_{ESHG:(V,E)}$ could be different and it's not unique. To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\\
The obvious SuperHyperGraph has no neutrosophic SuperHyperEdges. But the non-obvious neutrosophic SuperHyperModel is up. The quasi-SuperHyperModel addresses some issues about the neutrosophic optimal SuperHyperObject. It specially delivers some remarks on the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that there's distinct amount of neutrosophic SuperHyperEdges for distinct amount of neutrosophic SuperHyperVertices up to all taken from that neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices but this neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices is either has the maximum neutrosophic SuperHyperCardinality or it doesn't have maximum neutrosophic SuperHyperCardinality. In a non-obvious SuperHyperModel, there's at least one neutrosophic SuperHyperEdge containing at least all neutrosophic SuperHyperVertices. Thus it forms a neutrosophic quasi-R-SuperHyperMatching where the neutrosophic completion of the neutrosophic incidence is up in that. Thus it's, literarily, a neutrosophic embedded R-SuperHyperMatching. The SuperHyperNotions of embedded SuperHyperSet and quasi-SuperHyperSet coincide. In the original setting, these types of SuperHyperSets only don't satisfy on the maximum SuperHyperCardinality. Thus the embedded setting is elected such that those SuperHyperSets have the maximum neutrosophic SuperHyperCardinality and they're neutrosophic SuperHyperOptimal. The less than two distinct types of neutrosophic SuperHyperVertices are included in the minimum neutrosophic style of the embedded neutrosophic R-SuperHyperMatching. The interior types of the neutrosophic SuperHyperVertices are deciders. Since the neutrosophic number of SuperHyperNeighbors are only affected by the interior neutrosophic SuperHyperVertices. The common connections, more precise and more formal, the perfect unique connections inside the neutrosophic SuperHyperSet for any distinct types of neutrosophic SuperHyperVertices pose the neutrosophic R-SuperHyperMatching. Thus neutrosophic exterior SuperHyperVertices could be used only in one neutrosophic SuperHyperEdge and in neutrosophic SuperHyperRelation with the interior neutrosophic SuperHyperVertices in that neutrosophic SuperHyperEdge. In the embedded neutrosophic SuperHyperMatching, there's the usage of exterior neutrosophic SuperHyperVertices since they've more connections inside more than outside. Thus the title ``exterior'' is more relevant than the title ``interior''. One neutrosophic SuperHyperVertex has no connection, inside. Thus, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices with one SuperHyperElement has been ignored in the exploring to lead on the optimal case implying the neutrosophic R-SuperHyperMatching. The neutrosophic R-SuperHyperMatching with the exclusion of the exclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge and with other terms, the neutrosophic R-SuperHyperMatching with the inclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge, is a neutrosophic quasi-R-SuperHyperMatching. To sum them up, in a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\\
The main definition of the neutrosophic R-SuperHyperMatching has two titles. a neutrosophic quasi-R-SuperHyperMatching and its corresponded quasi-maximum neutrosophic R-SuperHyperCardinality are two titles in the terms of quasi-R-styles. For any neutrosophic number, there's a neutrosophic quasi-R-SuperHyperMatching with that quasi-maximum neutrosophic SuperHyperCardinality in the terms of the embedded neutrosophic SuperHyperGraph. If there's an embedded neutrosophic SuperHyperGraph, then the neutrosophic quasi-SuperHyperNotions lead us to take the collection of all the neutrosophic quasi-R-SuperHyperMatchings for all neutrosophic numbers less than its neutrosophic corresponded maximum number. The essence of the neutrosophic SuperHyperMatching ends up but this essence starts up in the terms of the neutrosophic quasi-R-SuperHyperMatching, again and more in the operations of collecting all the neutrosophic quasi-R-SuperHyperMatchings acted on the all possible used formations of the neutrosophic SuperHyperGraph to achieve one neutrosophic number. This neutrosophic number is considered as the equivalence class for all corresponded quasi-R-SuperHyperMatchings. Let $z_{\text{neutrosophic Number}},S_{\text{neutrosophic SuperHyperSet}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperSet and a neutrosophic SuperHyperMatching. Then
\begin{eqnarray*}
&&[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
As its consequences, the formal definition of the neutrosophic SuperHyperMatching is re-formalized and redefined as follows.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
To get more precise perceptions, the follow-up expressions propose another formal technical definition for the neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
In more concise and more convenient ways, the modified definition for the neutrosophic SuperHyperMatching poses the upcoming expressions.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
To translate the statement to this mathematical literature, the formulae will be revised.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
And then,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
To get more visions in the closer look-up, there's an overall overlook.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Now, the extension of these types of approaches is up. Since the new term, ``neutrosophic SuperHyperNeighborhood'', could be redefined as the collection of the neutrosophic SuperHyperVertices such that any amount of its neutrosophic SuperHyperVertices are incident to a neutrosophic SuperHyperEdge. It's, literarily, another name for ``neutrosophic Quasi-SuperHyperMatching'' but, precisely, it's the generalization of ``neutrosophic Quasi-SuperHyperMatching'' since ``neutrosophic Quasi-SuperHyperMatching'' happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and background but ``neutrosophic SuperHyperNeighborhood'' may not happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and preliminarily background since there are some ambiguities about the neutrosophic SuperHyperCardinality arise from it. To get orderly keywords, the terms, ``neutrosophic SuperHyperNeighborhood'', ``neutrosophic Quasi-SuperHyperMatching'', and ``neutrosophic SuperHyperMatching'' are up.
\\
Thus, let $z_{\text{neutrosophic Number}},N_{\text{neutrosophic SuperHyperNeighborhood}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperNeighborhood and a neutrosophic SuperHyperMatching and the new terms are up.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
And with go back to initial structure,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Let a neutrosophic SuperHyperEdge $ESHE: E\in E_{ESHG:(V,E)}$ has some neutrosophic SuperHyperVertices $r.$ Consider all neutrosophic numbers of those neutrosophic SuperHyperVertices from that neutrosophic SuperHyperEdge excluding excluding more than $r$ distinct neutrosophic SuperHyperVertices, exclude to any given neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices. Consider there's a neutrosophic R-SuperHyperMatching with the least cardinality, the lower sharp neutrosophic bound for neutrosophic cardinality. Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $ V_{ESHE}\setminus \{z\}$ is a neutrosophic SuperHyperSet $S$ of the neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely but it isn't a neutrosophic R-SuperHyperMatching. Since it doesn't have \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some SuperHyperVertices uniquely. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE}\cup \{z\}$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices but it isn't a neutrosophic R-SuperHyperMatching. Since it \textbf{\underline{doesn't do}} the neutrosophic procedure such that such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely [there are at least one neutrosophic SuperHyperVertex outside implying there's, sometimes in the connected neutrosophic SuperHyperGraph $ESHG:(V,E),$ a neutrosophic SuperHyperVertex, titled its neutrosophic SuperHyperNeighbor, to that neutrosophic SuperHyperVertex in the neutrosophic SuperHyperSet $S$ so as $S$ doesn't do ``the neutrosophic procedure''.]. There's only \textbf{\underline{one}} neutrosophic SuperHyperVertex \textbf{\underline{outside}} the intended neutrosophic SuperHyperSet, $V_{ESHE}\cup \{z\},$ in the terms of neutrosophic SuperHyperNeighborhood. Thus the obvious neutrosophic R-SuperHyperMatching, $V_{ESHE}$ is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching, $V_{ESHE},$ \textbf{\underline{is}} a neutrosophic SuperHyperSet, $V_{ESHE},$ \textbf{\underline{includes}} only \textbf{\underline{all}} neutrosophic SuperHyperVertices does forms any kind of neutrosophic pairs are titled \underline{neutrosophic SuperHyperNeighbors} in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE},$ is the \textbf{\underline{maximum neutrosophic SuperHyperCardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices \textbf{\underline{such that}} there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely. Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\\
The SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=z^{\min|P_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}. \\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\end{proof}
\begin{example}\label{119EXM22a}
In the Figure \eqref{119NSHG22a}, the connected neutrosophic SuperHyperMultipartite $ESHM:(V,E),$ is highlighted and neutrosophic featured. The obtained neutrosophic SuperHyperSet, by the Algorithm in previous neutrosophic result, of the neutrosophic SuperHyperVertices of the connected neutrosophic SuperHyperMultipartite $ESHM:(V,E),$ in the neutrosophic SuperHyperModel \eqref{119NSHG22a}, is the neutrosophic SuperHyperMatching.
\begin{figure}
\includegraphics[width=100mm]{119NSHG22.png}
\caption{a neutrosophic SuperHyperMultipartite Associated to the Notions of neutrosophic SuperHyperMatching in the Example \eqref{119EXM22a}}
\label{119NSHG22a}
\end{figure}
\end{example}
\begin{proposition}
Assume a connected neutrosophic SuperHyperWheel $ESHW:(V,E).$ Then a neutrosophic R-SuperHyperMatching is a neutrosophic SuperHyperSet of the interior neutrosophic SuperHyperVertices, excluding the neutrosophic SuperHyperCenter, with only no exception in the form of interior neutrosophic SuperHyperVertices from same neutrosophic SuperHyperEdge with the exclusion on neutrosophic SuperHypeNeighbors to some of them and not all. a neutrosophic R-SuperHyperMatching has the neutrosophic maximum number on all the neutrosophic number of all the neutrosophic SuperHyperEdges don't have common neutrosophic SuperHyperNeighbors. Also,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
\end{proposition}
\begin{proof}
Assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ The SuperHyperSet of the SuperHyperVertices $V\setminus V\setminus \{z\}$ isn't a quasi-R-SuperHyperMatching since neither amount of neutrosophic SuperHyperEdges nor amount of SuperHyperVertices where amount refers to the neutrosophic number of SuperHyperVertices(-/SuperHyperEdges) more than one to form any kind of SuperHyperEdges or any number of SuperHyperEdges. Let us consider the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
This neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices has the eligibilities to propose property such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices but the maximum neutrosophic cardinality indicates that these neutrosophic type-SuperHyperSets couldn't give us the neutrosophic lower bound in the term of neutrosophic sharpness. In other words, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices implies at least on-quasi-triangle style is up but sometimes the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
of the neutrosophic SuperHyperVertices is free-quasi-triangle and it doesn't make a contradiction to the supposition on the connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Thus the minimum case never happens in the generality of the connected loopless neutrosophic SuperHyperGraphs. Thus if we assume in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a quasi-R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a quasi-R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Then we've lost some connected loopless neutrosophic SuperHyperClasses of the connected loopless neutrosophic SuperHyperGraphs titled free-triangle, on-triangle, and their quasi-types but the SuperHyperStable is only up in this quasi-R-SuperHyperMatching. It's the contradiction to that fact on the generality. There are some counterexamples to deny this statement. One of them comes from the setting of the graph titled path and cycle as the counterexamples-classes or reversely direction star as the examples-classes, are well-known classes in that setting and they could be considered as the examples-classes and counterexamples-classes for the tight bound of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Let $V\setminus V\setminus \{z\}$ in mind. There's no necessity on the SuperHyperEdge since we need at least two SuperHyperVertices to form a SuperHyperEdge. It doesn't withdraw the principles of the main definition since there's no condition to be satisfied but the condition is on the existence of the SuperHyperEdge instead of acting on the SuperHyperVertices. In other words, if there's a SuperHyperEdge, then the neutrosophic SuperHyperSet has the necessary condition for the intended definition to be applied. Thus the $V\setminus V\setminus \{z\}$ is withdrawn not by the conditions of the main definition but by the necessity of the pre-condition on the usage of the main definition.
\\
The neutrosophic structure of the neutrosophic R-SuperHyperMatching decorates the neutrosophic SuperHyperVertices don't have received any neutrosophic connections so as this neutrosophic style implies different versions of neutrosophic SuperHyperEdges with the maximum neutrosophic cardinality in the terms of neutrosophic SuperHyperVertices are spotlight. The lower neutrosophic bound is to have the maximum neutrosophic groups of neutrosophic SuperHyperVertices have perfect neutrosophic connections inside each of SuperHyperEdges and the outside of this neutrosophic SuperHyperSet doesn't matter but regarding the connectedness of the used neutrosophic SuperHyperGraph arising from its neutrosophic properties taken from the fact that it's simple. If there's no more than one neutrosophic SuperHyperVertex in the targeted neutrosophic SuperHyperSet, then there's no neutrosophic connection. Furthermore, the neutrosophic existence of one neutrosophic SuperHyperVertex has no neutrosophic effect to talk about the neutrosophic R-SuperHyperMatching. Since at least two neutrosophic SuperHyperVertices involve to make a title in the neutrosophic background of the neutrosophic SuperHyperGraph. The neutrosophic SuperHyperGraph is obvious if it has no neutrosophic SuperHyperEdge but at least two neutrosophic SuperHyperVertices make the neutrosophic version of neutrosophic SuperHyperEdge. Thus in the neutrosophic setting of non-obvious neutrosophic SuperHyperGraph, there are at least one neutrosophic SuperHyperEdge. It's necessary to mention that the word ``Simple'' is used as neutrosophic adjective for the initial neutrosophic SuperHyperGraph, induces there's no neutrosophic appearance of the loop neutrosophic version of the neutrosophic SuperHyperEdge and this neutrosophic SuperHyperGraph is said to be loopless. The neutrosophic adjective ``loop'' on the basic neutrosophic framework engages one neutrosophic SuperHyperVertex but it never happens in this neutrosophic setting. With these neutrosophic bases, on a neutrosophic SuperHyperGraph, there's at least one neutrosophic SuperHyperEdge thus there's at least a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality of a neutrosophic SuperHyperEdge. Thus, a neutrosophic R-SuperHyperMatching has the neutrosophic cardinality at least a neutrosophic SuperHyperEdge. Assume a neutrosophic SuperHyperSet $V\setminus V\setminus \{z\}.$ This neutrosophic SuperHyperSet isn't a neutrosophic R-SuperHyperMatching since either the neutrosophic SuperHyperGraph is an obvious neutrosophic SuperHyperModel thus it never happens since there's no neutrosophic usage of this neutrosophic framework and even more there's no neutrosophic connection inside or the neutrosophic SuperHyperGraph isn't obvious and as its consequences, there's a neutrosophic contradiction with the term ``neutrosophic R-SuperHyperMatching'' since the maximum neutrosophic cardinality never happens for this neutrosophic style of the neutrosophic SuperHyperSet and beyond that there's no neutrosophic connection inside as mentioned in first neutrosophic case in the forms of drawback for this selected neutrosophic SuperHyperSet. Let
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Comes up. This neutrosophic case implies having the neutrosophic style of on-quasi-triangle neutrosophic style on the every neutrosophic elements of this neutrosophic SuperHyperSet. Precisely, the neutrosophic R-SuperHyperMatching is the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that some neutrosophic amount of the neutrosophic SuperHyperVertices are on-quasi-triangle neutrosophic style. The neutrosophic cardinality of the v SuperHypeSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots,a_{E'},b_{E'},c_{E'},\ldots\right\}_{E,E'=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}$$
Is the maximum in comparison to the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But the lower neutrosophic bound is up. Thus the minimum neutrosophic cardinality of the maximum neutrosophic cardinality ends up the neutrosophic discussion. The first neutrosophic term refers to the neutrosophic setting of the neutrosophic SuperHyperGraph but this key point is enough since there's a neutrosophic SuperHyperClass of a neutrosophic SuperHyperGraph has no on-quasi-triangle neutrosophic style amid some amount of its neutrosophic SuperHyperVertices. This neutrosophic setting of the neutrosophic SuperHyperModel proposes a neutrosophic SuperHyperSet has only some amount neutrosophic SuperHyperVertices from one neutrosophic SuperHyperEdge such that there's no neutrosophic amount of neutrosophic SuperHyperEdges more than one involving these some amount of these neutrosophic SuperHyperVertices. The neutrosophic cardinality of this neutrosophic SuperHyperSet is the maximum and the neutrosophic case is occurred in the minimum neutrosophic situation. To sum them up, the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Has the maximum neutrosophic cardinality such that
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Contains some neutrosophic SuperHyperVertices such that there's distinct-covers-order-amount neutrosophic SuperHyperEdges for amount of neutrosophic SuperHyperVertices taken from the neutrosophic SuperHyperSet
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
It means that the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is a neutrosophic R-SuperHyperMatching for the neutrosophic SuperHyperGraph as used neutrosophic background in the neutrosophic terms of worst neutrosophic case and the common theme of the lower neutrosophic bound occurred in the specific neutrosophic SuperHyperClasses of the neutrosophic SuperHyperGraphs which are neutrosophic free-quasi-triangle.
\\
Assume a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic number of the neutrosophic SuperHyperVertices. Then every neutrosophic SuperHyperVertex has at least no neutrosophic SuperHyperEdge with others in common. Thus those neutrosophic SuperHyperVertices have the eligibles to be contained in a neutrosophic R-SuperHyperMatching. Those neutrosophic SuperHyperVertices are potentially included in a neutrosophic style-R-SuperHyperMatching. Formally, consider
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
Are the neutrosophic SuperHyperVertices of a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z.$$ where the $\sim$ isn't an equivalence relation but only the symmetric relation on the neutrosophic SuperHyperVertices of the neutrosophic SuperHyperGraph. The formal definition is as follows. $$Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z$$ if and only if $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices and there's only and only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ between the neutrosophic SuperHyperVertices $Z_i$ and $Z_j.$ The other definition for the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ in the terms of neutrosophic R-SuperHyperMatching is
$$\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}.$$
This definition coincides with the definition of the neutrosophic R-SuperHyperMatching but with slightly differences in the maximum neutrosophic cardinality amid those neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperVertices. Thus the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$\max_z|\{Z_1,Z_2,\ldots,Z_z~|~Z_i\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}|_{\text{neutrosophic cardinality}},$$
and
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is formalized with mathematical literatures on the neutrosophic R-SuperHyperMatching. Let $Z_i\overset E\sim Z_j,$ be defined as $Z_i$ and $Z_j$ are the neutrosophic SuperHyperVertices belong to the neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}.$ Thus,
$$E=\{Z_1,Z_2,\ldots,Z_z~|~Z_i\overset E\sim Z_j,~i\neq j,~ i,j=1,2,\ldots,z\}.$$
Or
$$\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
But with the slightly differences,
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
\{Z_1,Z_2,\ldots,Z_z~|~\forall i\neq j,~ i,j=1,2,\ldots,z,~\exists E_x,~Z_i\overset{E_x}\sim Z_j,\}.
\end{eqnarray*}
\begin{eqnarray*}
&&
\text{neutrosophic R-SuperHyperMatching}=
\\&&
V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.
\end{eqnarray*}
Thus $E\in E_{ESHG:(V,E)}$ is a neutrosophic quasi-R-SuperHyperMatching where $E\in E_{ESHG:(V,E)}$ is fixed that means $E_x=E\in E_{ESHG:(V,E)}.$ for all neutrosophic intended SuperHyperVertices but in a neutrosophic SuperHyperMatching, $E_x=E\in E_{ESHG:(V,E)}$ could be different and it's not unique. To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ If a neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has $z$ neutrosophic SuperHyperVertices, then the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least
$$V\setminus (V\setminus\left\{a_{E},b_{E},c_{E},\ldots,z_{E}\right\}).$$
It's straightforward that the neutrosophic cardinality of the neutrosophic R-SuperHyperMatching is at least the maximum neutrosophic number of neutrosophic SuperHyperVertices of the neutrosophic SuperHyperEdges with the maximum number of the neutrosophic SuperHyperEdges. In other words, the maximum number of the neutrosophic SuperHyperEdges contains the maximum neutrosophic number of neutrosophic SuperHyperVertices are renamed to neutrosophic SuperHyperMatching in some cases but the maximum number of the neutrosophic SuperHyperEdge with the maximum neutrosophic number of neutrosophic SuperHyperVertices, has the neutrosophic SuperHyperVertices are contained in a neutrosophic R-SuperHyperMatching.
\\
The obvious SuperHyperGraph has no neutrosophic SuperHyperEdges. But the non-obvious neutrosophic SuperHyperModel is up. The quasi-SuperHyperModel addresses some issues about the neutrosophic optimal SuperHyperObject. It specially delivers some remarks on the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices such that there's distinct amount of neutrosophic SuperHyperEdges for distinct amount of neutrosophic SuperHyperVertices up to all taken from that neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices but this neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices is either has the maximum neutrosophic SuperHyperCardinality or it doesn't have maximum neutrosophic SuperHyperCardinality. In a non-obvious SuperHyperModel, there's at least one neutrosophic SuperHyperEdge containing at least all neutrosophic SuperHyperVertices. Thus it forms a neutrosophic quasi-R-SuperHyperMatching where the neutrosophic completion of the neutrosophic incidence is up in that. Thus it's, literarily, a neutrosophic embedded R-SuperHyperMatching. The SuperHyperNotions of embedded SuperHyperSet and quasi-SuperHyperSet coincide. In the original setting, these types of SuperHyperSets only don't satisfy on the maximum SuperHyperCardinality. Thus the embedded setting is elected such that those SuperHyperSets have the maximum neutrosophic SuperHyperCardinality and they're neutrosophic SuperHyperOptimal. The less than two distinct types of neutrosophic SuperHyperVertices are included in the minimum neutrosophic style of the embedded neutrosophic R-SuperHyperMatching. The interior types of the neutrosophic SuperHyperVertices are deciders. Since the neutrosophic number of SuperHyperNeighbors are only affected by the interior neutrosophic SuperHyperVertices. The common connections, more precise and more formal, the perfect unique connections inside the neutrosophic SuperHyperSet for any distinct types of neutrosophic SuperHyperVertices pose the neutrosophic R-SuperHyperMatching. Thus neutrosophic exterior SuperHyperVertices could be used only in one neutrosophic SuperHyperEdge and in neutrosophic SuperHyperRelation with the interior neutrosophic SuperHyperVertices in that neutrosophic SuperHyperEdge. In the embedded neutrosophic SuperHyperMatching, there's the usage of exterior neutrosophic SuperHyperVertices since they've more connections inside more than outside. Thus the title ``exterior'' is more relevant than the title ``interior''. One neutrosophic SuperHyperVertex has no connection, inside. Thus, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices with one SuperHyperElement has been ignored in the exploring to lead on the optimal case implying the neutrosophic R-SuperHyperMatching. The neutrosophic R-SuperHyperMatching with the exclusion of the exclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge and with other terms, the neutrosophic R-SuperHyperMatching with the inclusion of all neutrosophic SuperHyperVertices in one neutrosophic SuperHyperEdge, is a neutrosophic quasi-R-SuperHyperMatching. To sum them up, in a connected non-obvious neutrosophic SuperHyperGraph $ESHG:(V,E).$ There's only one neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only the maximum possibilities of the distinct interior neutrosophic SuperHyperVertices inside of any given neutrosophic quasi-R-SuperHyperMatching minus all neutrosophic SuperHypeNeighbor to some of them but not all of them. In other words, there's only an unique neutrosophic SuperHyperEdge $E\in E_{ESHG:(V,E)}$ has only two distinct neutrosophic SuperHyperVertices in an neutrosophic quasi-R-SuperHyperMatching, minus all neutrosophic SuperHypeNeighbor to some of them but not all of them.
\\
The main definition of the neutrosophic R-SuperHyperMatching has two titles. a neutrosophic quasi-R-SuperHyperMatching and its corresponded quasi-maximum neutrosophic R-SuperHyperCardinality are two titles in the terms of quasi-R-styles. For any neutrosophic number, there's a neutrosophic quasi-R-SuperHyperMatching with that quasi-maximum neutrosophic SuperHyperCardinality in the terms of the embedded neutrosophic SuperHyperGraph. If there's an embedded neutrosophic SuperHyperGraph, then the neutrosophic quasi-SuperHyperNotions lead us to take the collection of all the neutrosophic quasi-R-SuperHyperMatchings for all neutrosophic numbers less than its neutrosophic corresponded maximum number. The essence of the neutrosophic SuperHyperMatching ends up but this essence starts up in the terms of the neutrosophic quasi-R-SuperHyperMatching, again and more in the operations of collecting all the neutrosophic quasi-R-SuperHyperMatchings acted on the all possible used formations of the neutrosophic SuperHyperGraph to achieve one neutrosophic number. This neutrosophic number is considered as the equivalence class for all corresponded quasi-R-SuperHyperMatchings. Let $z_{\text{neutrosophic Number}},S_{\text{neutrosophic SuperHyperSet}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperSet and a neutrosophic SuperHyperMatching. Then
\begin{eqnarray*}
&&[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
As its consequences, the formal definition of the neutrosophic SuperHyperMatching is re-formalized and redefined as follows.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
To get more precise perceptions, the follow-up expressions propose another formal technical definition for the neutrosophic SuperHyperMatching.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
In more concise and more convenient ways, the modified definition for the neutrosophic SuperHyperMatching poses the upcoming expressions.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
To translate the statement to this mathematical literature, the formulae will be revised.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
And then,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
To get more visions in the closer look-up, there's an overall overlook.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{S_{\text{neutrosophic SuperHyperSet}}~|
\\&&~S_{\text{neutrosophic SuperHyperSet}}=G_{\text{neutrosophic SuperHyperMatching}},
\\&&~|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{S\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|S_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Now, the extension of these types of approaches is up. Since the new term, ``neutrosophic SuperHyperNeighborhood'', could be redefined as the collection of the neutrosophic SuperHyperVertices such that any amount of its neutrosophic SuperHyperVertices are incident to a neutrosophic SuperHyperEdge. It's, literarily, another name for ``neutrosophic Quasi-SuperHyperMatching'' but, precisely, it's the generalization of ``neutrosophic Quasi-SuperHyperMatching'' since ``neutrosophic Quasi-SuperHyperMatching'' happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and background but ``neutrosophic SuperHyperNeighborhood'' may not happens ``neutrosophic SuperHyperMatching'' in a neutrosophic SuperHyperGraph as initial framework and preliminarily background since there are some ambiguities about the neutrosophic SuperHyperCardinality arise from it. To get orderly keywords, the terms, ``neutrosophic SuperHyperNeighborhood'', ``neutrosophic Quasi-SuperHyperMatching'', and ``neutrosophic SuperHyperMatching'' are up.
\\
Thus, let $z_{\text{neutrosophic Number}},N_{\text{neutrosophic SuperHyperNeighborhood}}$ and $G_{\text{neutrosophic SuperHyperMatching}}$ be a neutrosophic number, a neutrosophic SuperHyperNeighborhood and a neutrosophic SuperHyperMatching and the new terms are up.
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\}.
\end{eqnarray*}
And with go back to initial structure,
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}=
\\&&
\cup_{z_{\text{neutrosophic Number}}}\{N_{\text{neutrosophic SuperHyperNeighborhood}}~|
\\&&~|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&=z_{\text{neutrosophic Number}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperNeighborhood}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max_{[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}}z_{\text{neutrosophic Number}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
\begin{eqnarray*}
&&G_{\text{neutrosophic SuperHyperMatching}}=
\\&&
\{N_{\text{neutrosophic SuperHyperNeighborhood}}\in\cup_{z_{\text{neutrosophic Number}}}[z_{\text{neutrosophic Number}}]_{\text{neutrosophic Class}}~|~
\\&&
|N_{\text{neutrosophic SuperHyperSet}}|_{\text{neutrosophic Cardinality}}
\\&&
=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}
\}.
\end{eqnarray*}
Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
To make sense with the precise words in the terms of ``R-', the follow-up illustrations are coming up.
\\
The following neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching.
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
The neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is an \underline{\textbf{neutrosophic R-SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge amid some neutrosophic SuperHyperVertices instead of all given by \underline{\textbf{neutrosophic SuperHyperMatching}} is related to the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
There's \underline{not} only \underline{\textbf{one}} neutrosophic SuperHyperVertex \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{one}} neutrosophic SuperHyperVertex. But the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
doesn't have less than two SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet since they've come from at least so far an SuperHyperEdge. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of neutrosophic SuperHyperVertices,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices,
$$(V\setminus V\setminus \{x,z\})\cup\{xy\}$$ or $$(V\setminus V\setminus \{x,z\})\cup\{zy\}$$
is an neutrosophic R-SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some amount neutrosophic SuperHyperVertices instead of all given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching. There isn't only less than two neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Thus the non-obvious neutrosophic R-SuperHyperMatching,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is up. The non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
Is the neutrosophic SuperHyperSet, not:
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
does includes only less than two SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ but it's impossible in the case, they've corresponded to an SuperHyperEdge. It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic R-SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic R-SuperHyperMatching}},
\end{center}
is only and only
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E)$ with a illustrated SuperHyperModeling. It's also, not only a neutrosophic free-triangle embedded SuperHyperModel and a neutrosophic on-triangle embedded SuperHyperModel but also it's a neutrosophic stable embedded SuperHyperModel. But all only non-obvious simple neutrosophic type-SuperHyperSets of the neutrosophic R-SuperHyperMatching amid those obvious simple neutrosophic type-SuperHyperSets of the neutrosophic SuperHyperMatching, are
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\\
To sum them up, assume a connected loopless neutrosophic SuperHyperGraph $ESHG:(V,E).$ Then in the worst case, literally,
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
is a neutrosophic R-SuperHyperMatching. In other words, the least cardinality, the lower sharp bound for the cardinality, of a neutrosophic R-SuperHyperMatching is the cardinality of
$$V\setminus V\setminus\left\{a_{E},b_{E},c_{E},\ldots\right\}_{E=\left\{E\in E_{ESHG:(V,E)}~|~|E|=\max\left\{|E|~|~E\in E_{ESHG:(V,E)}\right\}\right\}}.$$
\\
To sum them up, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The all interior neutrosophic SuperHyperVertices belong to any neutrosophic quasi-R-SuperHyperMatching if for any of them, and any of other corresponded neutrosophic SuperHyperVertex, some interior neutrosophic SuperHyperVertices are mutually neutrosophic SuperHyperNeighbors with no neutrosophic exception at all minus all neutrosophic SuperHypeNeighbors to any amount of them.
\\
Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Let a neutrosophic SuperHyperEdge $ESHE: E\in E_{ESHG:(V,E)}$ has some neutrosophic SuperHyperVertices $r.$ Consider all neutrosophic numbers of those neutrosophic SuperHyperVertices from that neutrosophic SuperHyperEdge excluding excluding more than $r$ distinct neutrosophic SuperHyperVertices, exclude to any given neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices. Consider there's a neutrosophic R-SuperHyperMatching with the least cardinality, the lower sharp neutrosophic bound for neutrosophic cardinality. Assume a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $ V_{ESHE}\setminus \{z\}$ is a neutrosophic SuperHyperSet $S$ of the neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely but it isn't a neutrosophic R-SuperHyperMatching. Since it doesn't have \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's a neutrosophic SuperHyperEdge to have some SuperHyperVertices uniquely. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE}\cup \{z\}$ is the maximum neutrosophic cardinality of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices but it isn't a neutrosophic R-SuperHyperMatching. Since it \textbf{\underline{doesn't do}} the neutrosophic procedure such that such that there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely [there are at least one neutrosophic SuperHyperVertex outside implying there's, sometimes in the connected neutrosophic SuperHyperGraph $ESHG:(V,E),$ a neutrosophic SuperHyperVertex, titled its neutrosophic SuperHyperNeighbor, to that neutrosophic SuperHyperVertex in the neutrosophic SuperHyperSet $S$ so as $S$ doesn't do ``the neutrosophic procedure''.]. There's only \textbf{\underline{one}} neutrosophic SuperHyperVertex \textbf{\underline{outside}} the intended neutrosophic SuperHyperSet, $V_{ESHE}\cup \{z\},$ in the terms of neutrosophic SuperHyperNeighborhood. Thus the obvious neutrosophic R-SuperHyperMatching, $V_{ESHE}$ is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic R-SuperHyperMatching, $V_{ESHE},$ \textbf{\underline{is}} a neutrosophic SuperHyperSet, $V_{ESHE},$ \textbf{\underline{includes}} only \textbf{\underline{all}} neutrosophic SuperHyperVertices does forms any kind of neutrosophic pairs are titled \underline{neutrosophic SuperHyperNeighbors} in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperVertices $V_{ESHE},$ is the \textbf{\underline{maximum neutrosophic SuperHyperCardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices \textbf{\underline{such that}} there's a neutrosophic SuperHyperEdge to have some neutrosophic SuperHyperVertices uniquely. Thus, in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ Any neutrosophic R-SuperHyperMatching only contains all interior neutrosophic SuperHyperVertices and all exterior neutrosophic SuperHyperVertices from the unique neutrosophic SuperHyperEdge where there's any of them has all possible neutrosophic SuperHyperNeighbors in and there's all neutrosophic SuperHyperNeighborhoods in with no exception minus all neutrosophic SuperHypeNeighbors to some of them not all of them but everything is possible about neutrosophic SuperHyperNeighborhoods and neutrosophic SuperHyperNeighbors out.
\\
The SuperHyperNotion, namely, SuperHyperMatching, is up. There's neither empty SuperHyperEdge nor loop SuperHyperEdge. The following neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices] is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching.
The neutrosophic SuperHyperSet of neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
is the simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. The neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an \underline{\textbf{neutrosophic SuperHyperMatching}} $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is a neutrosophic type-SuperHyperSet with \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There are \underline{not} only \underline{\textbf{two}} neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious neutrosophic SuperHyperMatching is up. The obvious simple neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching is a neutrosophic SuperHyperSet \underline{\textbf{includes}} only \underline{\textbf{two}} neutrosophic SuperHyperVertices. But the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Doesn't have less than three SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet. Thus the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching \underline{\textbf{is}} up. To sum them up, the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}\underline{\textbf{Is}} the non-obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching. Since the neutrosophic SuperHyperSet of the neutrosophic SuperHyperEdges[SuperHyperVertices],
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is an neutrosophic SuperHyperMatching $\mathcal{C}(ESHG)$ for an neutrosophic SuperHyperGraph $ESHG:(V,E)$ is the neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperVertices such that there's no a neutrosophic SuperHyperEdge for some neutrosophic SuperHyperVertices given by that neutrosophic type-SuperHyperSet called the neutrosophic SuperHyperMatching \underline{\textbf{and}} it's an neutrosophic \underline{\textbf{ SuperHyperMatching}}. Since it\underline{\textbf{'s}} \underline{\textbf{the maximum neutrosophic cardinality}} of a neutrosophic SuperHyperSet $S$ of neutrosophic SuperHyperEdges[SuperHyperVertices] such that there's no neutrosophic SuperHyperVertex of a neutrosophic SuperHyperEdge is common and there's an neutrosophic SuperHyperEdge for all neutrosophic SuperHyperVertices. There aren't only less than three neutrosophic SuperHyperVertices \underline{\textbf{inside}} the intended neutrosophic SuperHyperSet,
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Thus the non-obvious neutrosophic SuperHyperMatching, \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is up. The obvious simple neutrosophic type-SuperHyperSet of the neutrosophic SuperHyperMatching, not: \begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Is the neutrosophic SuperHyperSet, not:
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
Does includes only less than three SuperHyperVertices in a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$ It's interesting to mention that the only non-obvious simple neutrosophic type-SuperHyperSet called the
\begin{center}
\underline{\textbf{``neutrosophic SuperHyperMatching''}}
\end{center}
amid those obvious[non-obvious] simple neutrosophic type-SuperHyperSets called the
\begin{center}
\underline{\textbf{neutrosophic SuperHyperMatching}},
\end{center}
is only and only
\begin{eqnarray*}
&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching}
\\&&=\{E_{2i-1}\}_{i=1}^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic Quasi-SuperHyperMatching SuperHyperPolynomial}
\\&&=2z^{\lfloor\frac{|E_{ESHG:(V,E)}|_{\text{neutrosophic Cardinality}}}{2}\rfloor}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching}=\{V_i\}_{i=1}^{s},\{V_j\}_{j=1}^{t}.
\\&&
\mathcal{C}(NSHG)_{neutrosophic R-Quasi-SuperHyperMatching SuperHyperPolynomial}=az^{s}+bz^{t}.
\end{eqnarray*}
In a connected neutrosophic SuperHyperGraph $ESHG:(V,E).$
\end{proof}
\begin{example}\label{119EXM23a}
In the neutrosophic Figure \eqref{119NSHG23a}, the connected neutrosophic SuperHyperWheel $NSHW:(V,E),$ is neutrosophic highlighted and featured. The obtained neutrosophic SuperHyperSet, by the Algorithm in previous result, of the neutrosophic SuperHyperVertices of the connected neutrosophic SuperHyperWheel $ESHW:(V,E),$
in the neutrosophic SuperHyperModel \eqref{119NSHG23a}, is the neutrosophic SuperHyperMatching.
\begin{figure}
\includegraphics[width=100mm]{119NSHG23.png}
\caption{a neutrosophic SuperHyperWheel neutrosophic Associated to the neutrosophic Notions of neutrosophic SuperHyperMatching in the neutrosophic Example \eqref{119EXM23a}}
\label{104NSHG23a}
\end{figure}
\end{example}
\section{General neutrosophic Results}
For the SuperHyperMatching, neutrosophic SuperHyperMatching, and the neutrosophic SuperHyperMatching, some general results are introduced.
\begin{remark}
Let remind that the neutrosophic SuperHyperMatching is ``redefined'' on the positions of the alphabets.
\end{remark}
\begin{corollary}
Assume neutrosophic SuperHyperMatching. Then
\begin{eqnarray*}
&& Neutrosophic ~SuperHyperMatching=\\&&\{the SuperHyperMatching of the SuperHyperVertices ~|~\\&&\max|SuperHyperOffensive SuperHyper\\&&Clique|_{neutrosophic cardinality amid those SuperHyperMatching.}\}
\end{eqnarray*}
plus one neutrosophic SuperHypeNeighbor to one. Where $\sigma_i$ is the unary operation on the SuperHyperVertices of the SuperHyperGraph to assign the determinacy, the indeterminacy and the neutrality, for $i=1,2,3,$ respectively.
\end{corollary}
\begin{corollary}
Assume a neutrosophic SuperHyperGraph on the same identical letter of the alphabet. Then the notion of neutrosophic SuperHyperMatching and SuperHyperMatching coincide.
\end{corollary}
\begin{corollary}
Assume a neutrosophic SuperHyperGraph on the same identical letter of the alphabet. Then a consecutive sequence of the SuperHyperVertices is a neutrosophic SuperHyperMatching if and only if it's a SuperHyperMatching.
\end{corollary}
\begin{corollary}
Assume a neutrosophic SuperHyperGraph on the same identical letter of the alphabet. Then a consecutive sequence of the SuperHyperVertices is a strongest SuperHyperCycle if and only if it's a longest SuperHyperCycle.
\end{corollary}
\begin{corollary}
Assume SuperHyperClasses of a neutrosophic SuperHyperGraph on the same identical letter of the alphabet. Then its neutrosophic SuperHyperMatching is its SuperHyperMatching and reversely.
\end{corollary}
\begin{corollary}
Assume a neutrosophic SuperHyperPath(-/SuperHyperCycle, SuperHyperStar, SuperHyperBipartite, SuperHyperMultipartite, SuperHyperWheel) on the same identical letter of the alphabet. Then its neutrosophic SuperHyperMatching is its SuperHyperMatching and reversely.
\end{corollary}
\begin{corollary}
Assume a neutrosophic SuperHyperGraph. Then its neutrosophic SuperHyperMatching isn't well-defined if and only if its SuperHyperMatching isn't well-defined.
\end{corollary}
\begin{corollary}
Assume SuperHyperClasses of a neutrosophic SuperHyperGraph. Then its neutrosophic SuperHyperMatching isn't well-defined if and only if its SuperHyperMatching isn't well-defined.
\end{corollary}
\begin{corollary}
Assume a neutrosophic SuperHyperPath(-/SuperHyperCycle, SuperHyperStar, SuperHyperBipartite, SuperHyperMultipartite, SuperHyperWheel). Then its neutrosophic SuperHyperMatching isn't well-defined if and only if its SuperHyperMatching isn't well-defined.
\end{corollary}
\begin{corollary}
Assume a neutrosophic SuperHyperGraph. Then its neutrosophic SuperHyperMatching is well-defined if and only if its SuperHyperMatching is well-defined.
\end{corollary}
\begin{corollary}
Assume SuperHyperClasses of a neutrosophic SuperHyperGraph. Then its neutrosophic SuperHyperMatching is well-defined if and only if its SuperHyperMatching is well-defined.
\end{corollary}
\begin{corollary}
Assume a neutrosophic SuperHyperPath(-/SuperHyperCycle, SuperHyperStar, SuperHyperBipartite, SuperHyperMultipartite, SuperHyperWheel). Then its neutrosophic SuperHyperMatching is well-defined if and only if its SuperHyperMatching is well-defined.
\end{corollary}
%
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph. Then $V$ is
\begin{itemize}
\item[$(i):$] the dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] the strong dual SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] the connected dual SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] the $\delta$-dual SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] the strong $\delta$-dual SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] the connected $\delta$-dual SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperGraph. Consider $V.$ All SuperHyperMembers of $V$ have at least one SuperHyperNeighbor inside the SuperHyperSet more than SuperHyperNeighbor out of SuperHyperSet. Thus,
\\
$(i).$ $V$ is the dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in V,~|N(a)\cap V|>|N(a)\cap (V\setminus V)| \equiv \\&& \forall a\in V,~|N(a)\cap V|>|N(a)\cap \emptyset| \equiv \\&& \forall a\in V,~|N(a)\cap V|>|\emptyset| \equiv \\&& \forall a\in V,~|N(a)\cap V|>0 \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$(ii).$ $V$ is the strong dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_s(a)\cap S|>|N_s(a)\cap (V\setminus S)| \equiv \\&& \forall a\in V,~|N_s(a)\cap V|>|N_s(a)\cap (V\setminus V)| \equiv \\&& \forall a\in V,~|N_s(a)\cap V|>|N_s(a)\cap \emptyset| \equiv \\&& \forall a\in V,~|N_s(a)\cap V|>|\emptyset| \equiv \\&& \forall a\in V,~|N_s(a)\cap V|>0 \equiv \\&& \forall a\in V,~\delta>0.\end{eqnarray*}
$(iii).$ $V$ is the connected dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_c(a)\cap S|>|N_c(a)\cap (V\setminus S)| \equiv \\&& \forall a\in V,~|N_c(a)\cap V|>|N_c(a)\cap (V\setminus V)| \equiv \\&& \forall a\in V,~|N_c(a)\cap V|>|N_c(a)\cap \emptyset| \equiv \\&& \forall a\in V,~|N_c(a)\cap V|>|\emptyset| \equiv \\&& \forall a\in V,~|N_c(a)\cap V|>0 \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$(iv).$ $V$ is the $\delta$-dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N(a)\cap S)-(N(a)\cap (V\setminus S))| > \delta \equiv \\&&
\forall a\in V,~|(N(a)\cap V)-(N(a)\cap (V\setminus V))| > \delta \equiv \\&&
\forall a\in V,~|(N(a)\cap V)-(N(a)\cap (\emptyset))| > \delta \equiv \\&&
\forall a\in V,~|(N(a)\cap V)-(\emptyset)| > \delta \equiv \\&&
\forall a\in V,~|(N(a)\cap V)| > \delta.
\end{eqnarray*}
$(v).$ $V$ is the strong $\delta$-dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_s(a)\cap S)-(N_s(a)\cap (V\setminus S))| > \delta \equiv \\&&
\forall a\in V,~|(N_s(a)\cap V)-(N_s(a)\cap (V\setminus V))| > \delta \equiv \\&&
\forall a\in V,~|(N_s(a)\cap V)-(N_s(a)\cap (\emptyset))| > \delta \equiv \\&&
\forall a\in V,~|(N_s(a)\cap V)-(\emptyset)| > \delta \equiv \\&&
\forall a\in V,~|(N_s(a)\cap V)| > \delta.
\end{eqnarray*}
$(vi).$ $V$ is connected $\delta$-dual SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_c(a)\cap S)-(N_c(a)\cap (V\setminus S))| > \delta \equiv \\&&
\forall a\in V,~|(N_c(a)\cap V)-(N_c(a)\cap (V\setminus V))| > \delta \equiv \\&&
\forall a\in V,~|(N_c(a)\cap V)-(N_c(a)\cap (\emptyset))| > \delta \equiv \\&&
\forall a\in V,~|(N_c(a)\cap V)-(\emptyset)| > \delta \equiv \\&&
\forall a\in V,~|(N_c(a)\cap V)| > \delta.
\end{eqnarray*}
\end{proof}
\begin{proposition}
Let $NTG:(V,E,\sigma,\mu)$ be a neutrosophic SuperHyperGraph. Then $\emptyset$ is
\begin{itemize}
\item[$(i):$] the SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] the strong SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] the connected defensive SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] the $\delta$-SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] the strong $\delta$-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] the connected $\delta$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperGraph. Consider $\emptyset.$ All SuperHyperMembers of $\emptyset$ have no SuperHyperNeighbor inside the SuperHyperSet less than SuperHyperNeighbor out of SuperHyperSet. Thus,
\\
$(i).$ $\emptyset$ is the SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in \emptyset,~|N(a)\cap \emptyset|<|N(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in\emptyset,~|\emptyset|<|N(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in \emptyset,~0<|N(a)\cap V| \equiv \\&& \forall a\in \emptyset,~0<|N(a)\cap V| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$(ii).$ $\emptyset$ is the strong SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_s(a)\cap S|<|N_s(a)\cap (V\setminus S)| \equiv \\&& \forall a\in \emptyset,~|N_s(a)\cap \emptyset|<|N_s(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in\emptyset,~|\emptyset|<|N_s(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in \emptyset,~0<|N_s(a)\cap V| \equiv \\&& \forall a\in \emptyset,~0<|N_s(a)\cap V| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$(iii).$ $\emptyset$ is the connected SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_c(a)\cap S|<|N_c(a)\cap (V\setminus S)| \equiv \\&& \forall a\in \emptyset,~|N_c(a)\cap \emptyset|<|N_c(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in\emptyset,~|\emptyset|<|N_c(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in \emptyset,~0<|N_c(a)\cap V| \equiv \\&& \forall a\in \emptyset,~0<|N_c(a)\cap V| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$(iv).$ $\emptyset$ is the $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N(a)\cap S)-(N(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N(a)\cap \emptyset)-(N(a)\cap (V\setminus \emptyset))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N(a)\cap \emptyset)-(N(a)\cap (V))| < \delta \equiv \\&&
\forall a\in \emptyset,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
$(v).$ $\emptyset$ is the strong $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_s(a)\cap S)-(N_s(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N_s(a)\cap \emptyset)-(N_s(a)\cap (V\setminus \emptyset))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N_s(a)\cap \emptyset)-(N_s(a)\cap (V))| < \delta \equiv \\&&
\forall a\in \emptyset,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
$(vi).$ $\emptyset$ is the connected $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_c(a)\cap S)-(N_c(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N_c(a)\cap \emptyset)-(N_c(a)\cap (V\setminus \emptyset))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N_c(a)\cap \emptyset)-(N_c(a)\cap (V))| < \delta \equiv \\&&
\forall a\in \emptyset,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph. Then an independent SuperHyperSet is
\begin{itemize}
\item[$(i):$] the SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] the strong SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] the connected SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] the $\delta$-SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] the strong $\delta$-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] the connected $\delta$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperGraph. Consider $S.$ All SuperHyperMembers of $S$ have no SuperHyperNeighbor inside the SuperHyperSet less than SuperHyperNeighbor out of SuperHyperSet. Thus,
\\
$(i).$ An independent SuperHyperSet is the SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|\emptyset|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~0<|N(a)\cap V| \equiv \\&& \forall a\in S,~0<|N(a)| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$(ii).$ An independent SuperHyperSet is the strong SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_s(a)\cap S|<|N_s(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N_s(a)\cap S|<|N_s(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|\emptyset|<|N_s(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~0<|N_s(a)\cap V| \equiv \\&& \forall a\in S,~0<|N_s(a)| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$(iii).$ An independent SuperHyperSet is the connected SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_c(a)\cap S|<|N_c(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N_c(a)\cap S|<|N_c(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|\emptyset|<|N_c(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~0<|N_c(a)\cap V| \equiv \\&& \forall a\in S,~0<|N_c(a)| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$(iv).$ An independent SuperHyperSet is the $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N(a)\cap S)-(N(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in S,~|(N(a)\cap S)-(N(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in S,~|(N(a)\cap S)-(N(a)\cap (V))| < \delta \equiv \\&&
\forall a\in S,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
$(v).$ An independent SuperHyperSet is the strong $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_s(a)\cap S)-(N_s(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in S,~|(N_s(a)\cap S)-(N_s(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in S,~|(N_s(a)\cap S)-(N_s(a)\cap (V))| < \delta \equiv \\&&
\forall a\in S,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
$(vi).$ An independent SuperHyperSet is the connected $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_c(a)\cap S)-(N_c(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in S,~|(N_c(a)\cap S)-(N_c(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in S,~|(N_c(a)\cap S)-(N_c(a)\cap (V))| < \delta \equiv \\&&
\forall a\in S,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperUniform SuperHyperGraph which is a SuperHyperCycle/SuperHyperPath. Then $V$ is a maximal
\begin{itemize}
\item[$(i):$] SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $\mathcal{O}(ESHG)$-SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $\mathcal{O}(ESHG)$-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $\mathcal{O}(ESHG)$-SuperHyperDefensive SuperHyperMatching;
\end{itemize}
Where the exterior SuperHyperVertices and the interior SuperHyperVertices coincide.
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperGraph which is a SuperHyperUniform SuperHyperCycle/SuperHyperPath.\\
$(i).$
Consider one segment is out of $S$ which is SuperHyperDefensive SuperHyperMatching. This segment has $2t$ SuperHyperNeighbors in $S$, i.e, Suppose $x_{i_{i=1,2,\ldots,t}}\in V\setminus S$ such that $y_{i_{i=1,2,\ldots,t}},z_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}).$ By it's the exterior SuperHyperVertices and the interior SuperHyperVertices coincide and it's SuperHyperUniform SuperHyperCycle, $|N(x_{i_{i=1,2,\ldots,t}})|=|N(y_{i_{i=1,2,\ldots,t}})|=|N(z_{i_{i=1,2,\ldots,t}})|=2t.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|N(y_{i_{i=1,2,\ldots,t}})\cap S|< \\&&|N(y_{i_{i=1,2,\ldots,t}})\cap (V\setminus (V\setminus \{x_{i_{i=1,2,\ldots,t}}\}))| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|N(y_{i_{i=1,2,\ldots,t}})\cap S|< \\&&|N(y_{i_{i=1,2,\ldots,t}})\cap \{x_{i_{i=1,2,\ldots,t}}\})| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|\{z_1,z_2,\ldots,z_{t-1}\}|< \\&&|\{x_1,x_2,\ldots,x_{t-1}\})| \equiv \\&& \exists y\in S,~t-1<t-1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x_{i_{i=1,2,\ldots,t}}\}$ isn't SuperHyperDefensive SuperHyperMatching in a given SuperHyperUniform SuperHyperCycle.
\\
Consider one segment, with two segments related to the SuperHyperLeaves as exceptions, is out of $S$ which is SuperHyperDefensive SuperHyperMatching. This segment has $2t$ SuperHyperNeighbors in $S$, i.e, Suppose $x_{i_{i=1,2,\ldots,t}}\in V\setminus S$ such that $y_{i_{i=1,2,\ldots,t}},z_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}).$ By it's the exterior SuperHyperVertices and the interior SuperHyperVertices coincide and it's SuperHyperUniform SuperHyperPath, $|N(x_{i_{i=1,2,\ldots,t}})|=|N(y_{i_{i=1,2,\ldots,t}})|=|N(z_{i_{i=1,2,\ldots,t}})|=2t.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|N(y_{i_{i=1,2,\ldots,t}})\cap S|< \\&&|N(y_{i_{i=1,2,\ldots,t}})\cap (V\setminus (V\setminus \{x_{i_{i=1,2,\ldots,t}}\}))| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|N(y_{i_{i=1,2,\ldots,t}})\cap S|< \\&&|N(y_{i_{i=1,2,\ldots,t}})\cap \{x_{i_{i=1,2,\ldots,t}}\})| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|\{z_1,z_2,\ldots,z_{t-1}\}|< \\&&|\{x_1,x_2,\ldots,x_{t-1}\})| \equiv \\&& \exists y\in S,~t-1<t-1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x_{i_{i=1,2,\ldots,t}}\}$ isn't SuperHyperDefensive SuperHyperMatching in a given SuperHyperUniform SuperHyperPath.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $|V|$ is maximal and it's a SuperHyperDefensive SuperHyperMatching. Thus it's $|V|$-SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph which is a SuperHyperUniform SuperHyperWheel. Then $V$ is a maximal
\begin{itemize}
\item[$(i):$] dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong dual SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected dual SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $\mathcal{O}(ESHG)$-dual SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $\mathcal{O}(ESHG)$-dual SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $\mathcal{O}(ESHG)$-dual SuperHyperDefensive SuperHyperMatching;
\end{itemize}
Where the exterior SuperHyperVertices and the interior SuperHyperVertices coincide.
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperUniform SuperHyperGraph which is a SuperHyperWheel.\\
$(i).$ Consider one segment is out of $S$ which is SuperHyperDefensive SuperHyperMatching. This segment has $3t$ SuperHyperNeighbors in $S$, i.e, Suppose $x_{i_{i=1,2,\ldots,t}}\in V\setminus S$ such that $y_{i_{i=1,2,\ldots,t}},z_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}).$ By it's the exterior SuperHyperVertices and the interior SuperHyperVertices coincide and it's SuperHyperUniform SuperHyperWheel, $|N(x_{i_{i=1,2,\ldots,t}})|=|N(y_{i_{i=1,2,\ldots,t}})|=|N(z_{i_{i=1,2,\ldots,t}})|=3t.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}})\in V\setminus \{x_i\}_{i=1}^{t},\\&&~|N(y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}))\cap S|<\\&&|N(y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}))\cap (V\setminus (V\setminus \{x_{i_{i=1,2,\ldots,t}}\}))| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}})\in V\setminus \{x_i\}_{i=1}^{t},\\&&~|N(y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}))\cap S|<\\&&|N(y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}))\cap \{x_{i_{i=1,2,\ldots,t}}\})| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}})\in V\setminus \{x_i\}_{i=1}^{t},\\&&~|\{z_1,z_2,\ldots,z_{t-1},z'_1,z'_2,\ldots,z'_t\}|<|\{x_1,x_2,\ldots,x_{t-1}\})| \equiv \\&& \exists y\in S,~2t-1<t-1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x_{i_{i=1,2,\ldots,t}}\}$ is SuperHyperDefensive SuperHyperMatching in a given SuperHyperUniform SuperHyperWheel.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $|V|$ is maximal and it is a dual SuperHyperDefensive SuperHyperMatching. Thus it's a dual $|V|$-SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperUniform SuperHyperGraph which is a SuperHyperCycle/SuperHyperPath. Then the number of
\begin{itemize}
\item[$(i):$] the SuperHyperMatching;
\item[$(ii):$] the SuperHyperMatching;
\item[$(iii):$] the connected SuperHyperMatching;
\item[$(iv):$] the $\mathcal{O}(ESHG)$-SuperHyperMatching;
\item[$(v):$] the strong $\mathcal{O}(ESHG)$-SuperHyperMatching;
\item[$(vi):$] the connected $\mathcal{O}(ESHG)$-SuperHyperMatching.
\end{itemize}
is one and it's only $V.$ Where the exterior SuperHyperVertices and the interior SuperHyperVertices coincide.
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperGraph which is a SuperHyperUniform SuperHyperCycle/SuperHyperPath.\\
$(i).$
Consider one segment is out of $S$ which is SuperHyperDefensive SuperHyperMatching. This segment has $2t$ SuperHyperNeighbors in $S$, i.e, Suppose $x_{i_{i=1,2,\ldots,t}}\in V\setminus S$ such that $y_{i_{i=1,2,\ldots,t}},z_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}).$ By it's the exterior SuperHyperVertices and the interior SuperHyperVertices coincide and it's SuperHyperUniform SuperHyperCycle, $|N(x_{i_{i=1,2,\ldots,t}})|=|N(y_{i_{i=1,2,\ldots,t}})|=|N(z_{i_{i=1,2,\ldots,t}})|=2t.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|N(y_{i_{i=1,2,\ldots,t}})\cap S|<\\&&|N(y_{i_{i=1,2,\ldots,t}})\cap (V\setminus (V\setminus \{x_{i_{i=1,2,\ldots,t}}\}))| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|N(y_{i_{i=1,2,\ldots,t}})\cap S|<\\&&|N(y_{i_{i=1,2,\ldots,t}})\cap \{x_{i_{i=1,2,\ldots,t}}\})| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|\{z_1,z_2,\ldots,z_{t-1}\}|<|\{x_1,x_2,\ldots,x_{t-1}\})| \equiv \\&& \exists y\in S,~t-1<t-1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x_{i_{i=1,2,\ldots,t}}\}$ isn't SuperHyperDefensive SuperHyperMatching in a given SuperHyperUniform SuperHyperCycle.
\\
Consider one segment, with two segments related to the SuperHyperLeaves as exceptions, is out of $S$ which is SuperHyperDefensive SuperHyperMatching. This segment has $2t$ SuperHyperNeighbors in $S$, i.e, Suppose $x_{i_{i=1,2,\ldots,t}}\in V\setminus S$ such that $y_{i_{i=1,2,\ldots,t}},z_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}).$ By it's the exterior SuperHyperVertices and the interior SuperHyperVertices coincide and it's SuperHyperUniform SuperHyperPath, $|N(x_{i_{i=1,2,\ldots,t}})|=|N(y_{i_{i=1,2,\ldots,t}})|=|N(z_{i_{i=1,2,\ldots,t}})|=2t.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|N(y_{i_{i=1,2,\ldots,t}})\cap S|<\\&&|N(y_{i_{i=1,2,\ldots,t}})\cap (V\setminus (V\setminus \{x_{i_{i=1,2,\ldots,t}}\}))| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|N(y_{i_{i=1,2,\ldots,t}})\cap S|<\\&&|N(y_{i_{i=1,2,\ldots,t}})\cap \{x_{i_{i=1,2,\ldots,t}}\})| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}}\in V\setminus \{x_i\}_{i=1}^{t},~|\{z_1,z_2,\ldots,z_{t-1}\}|<\\&&|\{x_1,x_2,\ldots,x_{t-1}\})| \equiv \\&& \exists y\in S,~t-1<t-1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x_{i_{i=1,2,\ldots,t}}\}$ isn't SuperHyperDefensive SuperHyperMatching in a given SuperHyperUniform SuperHyperPath.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $|V|$ is maximal and it's a SuperHyperDefensive SuperHyperMatching. Thus it's $|V|$-SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperUniform SuperHyperGraph which is a SuperHyperWheel. Then the number of
\begin{itemize}
\item[$(i):$] the dual SuperHyperMatching;
\item[$(ii):$] the dual SuperHyperMatching;
\item[$(iii):$] the dual connected SuperHyperMatching;
\item[$(iv):$] the dual $\mathcal{O}(ESHG)$-SuperHyperMatching;
\item[$(v):$] the strong dual $\mathcal{O}(ESHG)$-SuperHyperMatching;
\item[$(vi):$] the connected dual $\mathcal{O}(ESHG)$-SuperHyperMatching.
\end{itemize}
is one and it's only $V.$ Where the exterior SuperHyperVertices and the interior SuperHyperVertices coincide.
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperUniform SuperHyperGraph which is a SuperHyperWheel.\\
$(i).$ Consider one segment is out of $S$ which is SuperHyperDefensive SuperHyperMatching. This segment has $3t$ SuperHyperNeighbors in $S$, i.e, Suppose $x_{i_{i=1,2,\ldots,t}}\in V\setminus S$ such that $y_{i_{i=1,2,\ldots,t}},z_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}).$ By it's the exterior SuperHyperVertices and the interior SuperHyperVertices coincide and it's SuperHyperUniform SuperHyperWheel, $|N(x_{i_{i=1,2,\ldots,t}})|=|N(y_{i_{i=1,2,\ldots,t}})|=|N(z_{i_{i=1,2,\ldots,t}})|=3t.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}})\in V\setminus \{x_i\}_{i=1}^{t},\\&&~|N(y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}))\cap S|<\\&&|N(y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}))\cap (V\setminus (V\setminus \{x_{i_{i=1,2,\ldots,t}}\}))| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}})\in V\setminus \{x_i\}_{i=1}^{t}\\&&,~|N(y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}))\cap S|<\\&&|N(y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}}))\cap \{x_{i_{i=1,2,\ldots,t}}\})| \equiv \\&& \exists y_{i_{i=1,2,\ldots,t}},s_{i_{i=1,2,\ldots,t}}\in N(x_{i_{i=1,2,\ldots,t}})\in V\setminus \{x_i\}_{i=1}^{t},\\&&~|\{z_1,z_2,\ldots,z_{t-1},z'_1,z'_2,\ldots,z'_t\}|<|\{x_1,x_2,\ldots,x_{t-1}\})| \equiv \\&& \exists y\in S,~2t-1<t-1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x_{i_{i=1,2,\ldots,t}}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperUniform SuperHyperWheel.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $|V|$ is maximal and it's a dual SuperHyperDefensive SuperHyperMatching. Thus it isn't an $|V|$-SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperUniform SuperHyperGraph which is a SuperHyperStar/SuperHyperComplete SuperHyperBipartite/SuperHyperComplete SuperHyperMultipartite. Then a SuperHyperSet contains [the SuperHyperCenter and] the half of multiplying $r$ with the number of all the SuperHyperEdges plus one of all the SuperHyperVertices is a
\begin{itemize}
\item[$(i):$] dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong dual SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected dual SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $\frac{\mathcal{O}(ESHG)}{2}+1$-dual SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $\frac{\mathcal{O}(ESHG)}{2}+1$-dual SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $\frac{\mathcal{O}(ESHG)}{2}+1$-dual SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has either $\frac{n}{2}$ or one SuperHyperNeighbors in $S.$ If the SuperHyperVertex is non-SuperHyperCenter, then
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~1>0.
\end{eqnarray*}
If the SuperHyperVertex is SuperHyperCenter, then
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperStar.
\\
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has at most $\frac{n}{2}$ SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~\frac{n}{2}>|N(a)\cap S|>\frac{n}{2}-1>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperBipartite which isn't a SuperHyperStar.
\\
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is SuperHyperDefensive SuperHyperMatching and they're chosen from different SuperHyperParts, equally or almost equally as possible. A SuperHyperVertex has at most $\frac{n}{2}$ SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~\frac{n}{2}>|N(a)\cap S|>\frac{n}{2}-1>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperMultipartite which is neither a SuperHyperStar nor SuperHyperComplete SuperHyperBipartite.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $\{x_i\}_{i=1}^{\frac{\mathcal{O}(ESHG)}{2}+1}$ is a dual SuperHyperDefensive SuperHyperMatching. Thus it's $\frac{\mathcal{O}(ESHG)}{2}+1$-dual SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperUniform SuperHyperGraph which is a SuperHyperStar/SuperHyperComplete SuperHyperBipartite/SuperHyperComplete SuperHyperMultipartite. Then a SuperHyperSet contains the half of multiplying $r$ with the number of all the SuperHyperEdges plus one of all the SuperHyperVertices in the biggest SuperHyperPart is a
\begin{itemize}
\item[$(i):$]
SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $\delta$-SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $\delta$-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $\delta$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$
Consider the half of multiplying $r$ with the number of all the SuperHyperEdges plus one of all the SuperHyperVertices in the biggest SuperHyperPart are in $S$ which is SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has either $n-1,1$ or zero SuperHyperNeighbors in $S.$ If the SuperHyperVertex is in $S,$ then
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~0<1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a SuperHyperDefensive SuperHyperMatching in a given SuperHyperStar.
\\
Consider the half of multiplying $r$ with the number of all the SuperHyperEdges plus one of all the SuperHyperVertices in the biggest SuperHyperPart are in $S$ which is SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has no SuperHyperNeighbor in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~0<\delta.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperBipartite which isn't a SuperHyperStar.
\\
Consider the half of multiplying $r$ with the number of all the SuperHyperEdges plus one of all the SuperHyperVertices in the biggest SuperHyperPart are in $S$ which is SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has no SuperHyperNeighbor in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~0<\delta.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperMultipartite which is neither a SuperHyperStar nor SuperHyperComplete SuperHyperBipartite.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $S$ is a SuperHyperDefensive SuperHyperMatching. Thus it's an $\delta$-SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperUniform SuperHyperGraph which is a SuperHyperStar/SuperHyperComplete SuperHyperBipartite/SuperHyperComplete SuperHyperMultipartite. Then Then the number of \begin{itemize}
\item[$(i):$] dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong dual SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected dual SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $\frac{\mathcal{O}(ESHG)}{2}+1$-dual SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $\frac{\mathcal{O}(ESHG)}{2}+1$-dual SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $\frac{\mathcal{O}(ESHG)}{2}+1$-dual SuperHyperDefensive SuperHyperMatching.
\end{itemize}
is one and it's only $S,$ a SuperHyperSet contains [the SuperHyperCenter and] the half of multiplying $r$ with the number of all the SuperHyperEdges plus one of all the SuperHyperVertices. Where the exterior SuperHyperVertices and the interior SuperHyperVertices coincide.
\end{proposition}
\begin{proof}
$(i).$
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has either $\frac{n}{2}$ or one SuperHyperNeighbors in $S.$ If the SuperHyperVertex is non-SuperHyperCenter, then
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~1>0.
\end{eqnarray*}
If the SuperHyperVertex is SuperHyperCenter, then
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperStar.
\\
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has at most $\frac{n}{2}$ SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~\frac{n}{2}>|N(a)\cap S|>\frac{n}{2}-1>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperBipartite which isn't a SuperHyperStar.
\\
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is SuperHyperDefensive SuperHyperMatching and they're chosen from different SuperHyperParts, equally or almost equally as possible. A SuperHyperVertex has at most $\frac{n}{2}$ SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~\frac{n}{2}>|N(a)\cap S|>\frac{n}{2}-1>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperMultipartite which is neither a SuperHyperStar nor SuperHyperComplete SuperHyperBipartite.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $\{x_i\}_{i=1}^{\frac{\mathcal{O}(ESHG)}{2}+1}$ is a dual SuperHyperDefensive SuperHyperMatching. Thus it's $\frac{\mathcal{O}(ESHG)}{2}+1$-dual SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph. The number of connected component is $|V-S|$ if there's a SuperHyperSet which is a dual
\begin{itemize}
\item[$(i):$] SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] SuperHyperMatching;
\item[$(v):$] strong 1-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected 1-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$
Consider some SuperHyperVertices are out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. These SuperHyperVertex-type have some SuperHyperNeighbors in $S $ but no SuperHyperNeighbor out of $S.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~1>0.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching and number of connected component is $|V-S|.$
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $S$ is a dual SuperHyperDefensive SuperHyperMatching. Thus it's a dual $1$-SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph. Then the number is at most $\mathcal{O}(ESHG)$ and the neutrosophic number is at most $\mathcal{O}_n(ESHG).$
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperGraph. Consider $V.$ All SuperHyperMembers of $V$ have at least one SuperHyperNeighbor inside the SuperHyperSet more than SuperHyperNeighbor out of SuperHyperSet. Thus,
\\
$V$ is a dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in V,~|N(a)\cap V|>|N(a)\cap (V\setminus V)| \equiv \\&& \forall a\in V,~|N(a)\cap V|>|N(a)\cap \emptyset| \equiv \\&& \forall a\in V,~|N(a)\cap V|>|\emptyset| \equiv \\&& \forall a\in V,~|N(a)\cap V|>0 \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$V$ is a dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_s(a)\cap S|>|N_s(a)\cap (V\setminus S)| \equiv \\&& \forall a\in V,~|N_s(a)\cap V|>|N_s(a)\cap (V\setminus V)| \equiv \\&& \forall a\in V,~|N_s(a)\cap V|>|N_s(a)\cap \emptyset| \equiv \\&& \forall a\in V,~|N_s(a)\cap V|>|\emptyset| \equiv \\&& \forall a\in V,~|N_s(a)\cap V|>0 \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$V$ is connected a dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_c(a)\cap S|>|N_c(a)\cap (V\setminus S)| \equiv \\&& \forall a\in V,~|N_c(a)\cap V|>|N_c(a)\cap (V\setminus V)| \equiv \\&& \forall a\in V,~|N_c(a)\cap V|>|N_c(a)\cap \emptyset| \equiv \\&& \forall a\in V,~|N_c(a)\cap V|>|\emptyset| \equiv \\&& \forall a\in V,~|N_c(a)\cap V|>0 \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
$V$ is a dual $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N(a)\cap S)-(N(a)\cap (V\setminus S))| > \delta \equiv \\&&
\forall a\in V,~|(N(a)\cap V)-(N(a)\cap (V\setminus V))| > \delta \equiv \\&&
\forall a\in V,~|(N(a)\cap V)-(N(a)\cap (\emptyset))| > \delta \equiv \\&&
\forall a\in V,~|(N(a)\cap V)-(\emptyset)| > \delta \equiv \\&&
\forall a\in V,~|(N(a)\cap V)| > \delta.
\end{eqnarray*}
$V$ is a dual strong $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_s(a)\cap S)-(N_s(a)\cap (V\setminus S))| > \delta \equiv \\&&
\forall a\in V,~|(N_s(a)\cap V)-(N_s(a)\cap (V\setminus V))| > \delta \equiv \\&&
\forall a\in V,~|(N_s(a)\cap V)-(N_s(a)\cap (\emptyset))| > \delta \equiv \\&&
\forall a\in V,~|(N_s(a)\cap V)-(\emptyset)| > \delta \equiv \\&&
\forall a\in V,~|(N_s(a)\cap V)| > \delta.
\end{eqnarray*}
$V$ is a dual connected $\delta$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_c(a)\cap S)-(N_c(a)\cap (V\setminus S))| > \delta \equiv \\&&
\forall a\in V,~|(N_c(a)\cap V)-(N_c(a)\cap (V\setminus V))| > \delta \equiv \\&&
\forall a\in V,~|(N_c(a)\cap V)-(N_c(a)\cap (\emptyset))| > \delta \equiv \\&&
\forall a\in V,~|(N_c(a)\cap V)-(\emptyset)| > \delta \equiv \\&&
\forall a\in V,~|(N_c(a)\cap V)| > \delta.
\end{eqnarray*}
Thus $V$ is a dual SuperHyperDefensive SuperHyperMatching and $V$ is the biggest SuperHyperSet in $ESHG:(V,E).$ Then the number is at most $\mathcal{O}(ESHG:(V,E))$ and the neutrosophic number is at most $\mathcal{O}_n(ESHG:(V,E)).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph which is SuperHyperComplete. The number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of dual
\begin{itemize}
\item[$(i):$]
SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong
SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$
Consider $n$ half $-1$ SuperHyperVertices are out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has $n$ half SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1. \end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperGraph. Thus the number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of a dual SuperHyperDefensive SuperHyperMatching.
\\
$(ii).$
Consider $n$ half $-1$ SuperHyperVertices are out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has $n$ half SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1. \end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual strong SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperGraph. Thus the number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of a dual strong SuperHyperDefensive SuperHyperMatching.
\\
$(iii).$
Consider $n$ half $-1$ SuperHyperVertices are out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has $n$ half SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual connected SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperGraph. Thus the number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of a dual connected SuperHyperDefensive SuperHyperMatching.
\\
$(iv).$
Consider $n$ half $-1$ SuperHyperVertices are out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has $n$ half SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperGraph. Thus the number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of a dual $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching.
\\
$(v).$
Consider $n$ half $-1$ SuperHyperVertices are out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has $n$ half SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual strong $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperGraph. Thus the number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of a dual strong $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching.
\\
$(vi).$
Consider $n$ half $-1$ SuperHyperVertices are out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has $n$ half SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual connected $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching in a given SuperHyperComplete SuperHyperGraph. Thus the number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of a dual connected $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph which is $\emptyset.$ The number is $0$ and the neutrosophic number is $0,$ for an independent SuperHyperSet in the setting of dual
\begin{itemize}
\item[$(i):$] SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $0$-SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $0$-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $0$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperGraph. Consider $\emptyset.$ All SuperHyperMembers of $\emptyset$ have no SuperHyperNeighbor inside the SuperHyperSet less than SuperHyperNeighbor out of SuperHyperSet. Thus,
\\
$(i).$ $\emptyset$ is a dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in \emptyset,~|N(a)\cap \emptyset|<|N(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in\emptyset,~|\emptyset|<|N(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in \emptyset,~0<|N(a)\cap V| \equiv \\&& \forall a\in \emptyset,~0<|N(a)\cap V| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
The number is $0$ and the neutrosophic number is $0,$ for an independent SuperHyperSet in the setting of a dual SuperHyperDefensive SuperHyperMatching.
\\
$(ii).$ $\emptyset$ is a dual strong SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_s(a)\cap S|<|N_s(a)\cap (V\setminus S)| \equiv \\&& \forall a\in \emptyset,~|N_s(a)\cap \emptyset|<|N_s(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in\emptyset,~|\emptyset|<|N_s(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in \emptyset,~0<|N_s(a)\cap V| \equiv \\&& \forall a\in \emptyset,~0<|N_s(a)\cap V| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
The number is $0$ and the neutrosophic number is $0,$ for an independent SuperHyperSet in the setting of a dual strong SuperHyperDefensive SuperHyperMatching.
\\
$(iii).$ $\emptyset$ is a dual connected SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|N_c(a)\cap S|<|N_c(a)\cap (V\setminus S)| \equiv \\&& \forall a\in \emptyset,~|N_c(a)\cap \emptyset|<|N_c(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in\emptyset,~|\emptyset|<|N_c(a)\cap (V\setminus \emptyset)| \equiv \\&& \forall a\in \emptyset,~0<|N_c(a)\cap V| \equiv \\&& \forall a\in \emptyset,~0<|N_c(a)\cap V| \equiv \\&& \forall a\in V,~\delta>0.
\end{eqnarray*}
The number is $0$ and the neutrosophic number is $0,$ for an independent SuperHyperSet in the setting of a dual connected SuperHyperDefensive SuperHyperMatching.
\\
$(iv).$ $\emptyset$ is a dual SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N(a)\cap S)-(N(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N(a)\cap \emptyset)-(N(a)\cap (V\setminus \emptyset))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N(a)\cap \emptyset)-(N(a)\cap (V))| < \delta \equiv \\&&
\forall a\in \emptyset,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
The number is $0$ and the neutrosophic number is $0,$ for an independent SuperHyperSet in the setting of a dual $0$-SuperHyperDefensive SuperHyperMatching.
\\
$(v).$ $\emptyset$ is a dual strong $0$-SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_s(a)\cap S)-(N_s(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N_s(a)\cap \emptyset)-(N_s(a)\cap (V\setminus \emptyset))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N_s(a)\cap \emptyset)-(N_s(a)\cap (V))| < \delta \equiv \\&&
\forall a\in \emptyset,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
The number is $0$ and the neutrosophic number is $0,$ for an independent SuperHyperSet in the setting of a dual strong $0$-SuperHyperDefensive SuperHyperMatching.
\\
$(vi).$ $\emptyset$ is a dual connected SuperHyperDefensive SuperHyperMatching since the following statements are equivalent.
\begin{eqnarray*}&&
\forall a\in S,~|(N_c(a)\cap S)-(N_c(a)\cap (V\setminus S))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N_c(a)\cap \emptyset)-(N_c(a)\cap (V\setminus \emptyset))| < \delta \equiv \\&&
\forall a\in \emptyset,~|(N_c(a)\cap \emptyset)-(N_c(a)\cap (V))| < \delta \equiv \\&&
\forall a\in \emptyset,~|\emptyset| < \delta \equiv \\&&
\forall a\in V,~0 < \delta.
\end{eqnarray*}
The number is $0$ and the neutrosophic number is $0,$ for an independent SuperHyperSet in the setting of a dual connected $0$-offensive SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph which is SuperHyperComplete. Then there's no independent SuperHyperSet.
\end{proposition}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph which is SuperHyperCycle/SuperHyperPath/SuperHyperWheel. The number is $\mathcal{O}(ESHG:(V,E))$ and the neutrosophic number is $\mathcal{O}_n(ESHG:(V,E)),$ in the setting of a dual
\begin{itemize}
\item[$(i):$] SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $\mathcal{O}(ESHG:(V,E))$-SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $\mathcal{O}(ESHG:(V,E))$-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $\mathcal{O}(ESHG:(V,E))$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
Suppose $ESHG:(V,E)$ is a neutrosophic SuperHyperGraph which is SuperHyperCycle/SuperHyperPath/SuperHyperWheel. \\
$(i).$
Consider one SuperHyperVertex is out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. This SuperHyperVertex has one SuperHyperNeighbor in $S$, i.e, suppose $x\in V\setminus S$ such that $y,z\in N(x).$ By it's SuperHyperCycle, $|N(x)|=|N(y)|=|N(z)|=2.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y\in V\setminus \{x\},~|N(y)\cap S|<|N(y)\cap (V\setminus (V\setminus \{x\}))| \equiv \\&& \exists y\in V\setminus \{x\},~|N(y)\cap S|<|N(y)\cap \{x\})| \equiv \\&& \exists y\in V\setminus \{x\},~|\{z\}|<|\{x\})| \equiv \\&& \exists y\in S,~1<1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x\}$ isn't a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperCycle.
\\
Consider one SuperHyperVertex is out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. This SuperHyperVertex has one SuperHyperNeighbor in $S$, i.e, Suppose $x\in V\setminus S$ such that $y,z\in N(x).$ By it's SuperHyperPath, $|N(x)|=|N(y)|=|N(z)|=2.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y\in V\setminus \{x\},~|N(y)\cap S|<|N(y)\cap (V\setminus (V\setminus \{x\}))| \equiv \\&& \exists y\in V\setminus \{x\},~|N(y)\cap S|<|N(y)\cap \{x\})| \equiv \\&& \exists y\in V\setminus \{x\},~|\{z\}|<|\{x\})| \equiv \\&& \exists y\in S,~1<1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x\}$ isn't a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperPath.
\\
Consider one SuperHyperVertex is out of $S$ which is a dual SuperHyperDefensive SuperHyperMatching. This SuperHyperVertex has one SuperHyperNeighbor in $S$, i.e, Suppose $x\in V\setminus S$ such that $y,z\in N(x).$ By it's SuperHyperWheel, $|N(x)|=|N(y)|=|N(z)|=2.$ Thus
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \forall a\in S,~|N(a)\cap S|<|N(a)\cap (V\setminus S)| \equiv \\&& \exists y\in V\setminus \{x\},~|N(y)\cap S|<|N(y)\cap (V\setminus (V\setminus \{x\}))| \equiv \\&& \exists y\in V\setminus \{x\},~|N(y)\cap S|<|N(y)\cap \{x\})| \equiv \\&& \exists y\in V\setminus \{x\},~|\{z\}|<|\{x\})| \equiv \\&& \exists y\in S,~1<1.
\end{eqnarray*}
Thus it's contradiction. It implies every $V\setminus\{x\}$ isn't a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperWheel.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $V$ is maximal and it's a dual SuperHyperDefensive SuperHyperMatching. Thus it's a dual $\mathcal{O}(ESHG:(V,E))$-SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\\
Thus the number is $\mathcal{O}(ESHG:(V,E))$ and the neutrosophic number is $\mathcal{O}_n(ESHG:(V,E)),$ in the setting of all types of a dual SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a neutrosophic SuperHyperGraph which is SuperHyperStar/complete SuperHyperBipartite/complete SuperHyperMultiPartite. The number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of a dual
\begin{itemize}
\item[$(i):$] SuperHyperDefensive SuperHyperMatching;
\item[$(ii):$] strong SuperHyperDefensive SuperHyperMatching;
\item[$(iii):$] connected SuperHyperDefensive SuperHyperMatching;
\item[$(iv):$] $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching;
\item[$(v):$] strong $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching;
\item[$(vi):$] connected $(\frac{\mathcal{O}(ESHG:(V,E))}{2}+1)$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is SuperHyperDefensive SuperHyperMatching. A SuperHyperVertex has at most $n$ half SuperHyperNeighbors in $S.$ If the SuperHyperVertex is the non-SuperHyperCenter, then
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~1>0.
\end{eqnarray*}
If the SuperHyperVertex is the SuperHyperCenter, then
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{n}{2}>\frac{n}{2}-1.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given SuperHyperStar.
\\
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is a dual SuperHyperDefensive SuperHyperMatching.
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{\delta}{2}>n-\frac{\delta}{2}.
\end{eqnarray*}
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given complete SuperHyperBipartite which isn't a SuperHyperStar.
\\
Consider $n$ half $+1$ SuperHyperVertices are in $S$ which is a dual SuperHyperDefensive SuperHyperMatching and they are chosen from different SuperHyperParts, equally or almost equally as possible. A SuperHyperVertex in $S$ has $\delta$ half SuperHyperNeighbors in $S.$
\begin{eqnarray*}&&
\forall a\in S,~|N(a)\cap S|>|N(a)\cap (V\setminus S)|
\equiv \\&& \forall a\in S,~\frac{\delta}{2}>n-\frac{\delta}{2}.
\end{eqnarray*}
\\
Thus it's proved. It implies every $S$ is a dual SuperHyperDefensive SuperHyperMatching in a given complete SuperHyperMultipartite which is neither a SuperHyperStar nor complete SuperHyperBipartite.
\\
$(ii),$ $(iii)$ are obvious by $(i).$
\\
$(iv).$ By $(i),$ $\{x_i\}_{i=1}^{\frac{\mathcal{O}(ESHG:(V,E))}{2}+1}$ is maximal and it's a dual SuperHyperDefensive SuperHyperMatching. Thus it's a dual $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$-SuperHyperDefensive SuperHyperMatching.
\\
$(v),(vi)$ are obvious by $(iv).$
\\
Thus the number is $\frac{\mathcal{O}(ESHG:(V,E))}{2}+1$ and the neutrosophic number is $\min\Sigma_{v\in\{v_1,v_2,\cdots,v_t\}_{t>\frac{\mathcal{O}(ESHG:(V,E))}{2}}\subseteq V}\sigma(v),$ in the setting of all dual SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $\mathcal{NSHF}:(V,E)$ be a SuperHyperFamily of the $ESHGs:(V,E)$ neutrosophic SuperHyperGraphs which are from one-type SuperHyperClass which the result is obtained for the individuals. Then the results also hold for the SuperHyperFamily $\mathcal{NSHF}:(V,E)$ of these specific SuperHyperClasses of the neutrosophic SuperHyperGraphs.
\end{proposition}
\begin{proof}
There are neither SuperHyperConditions nor SuperHyperRestrictions on the SuperHyperVertices. Thus the SuperHyperResults on individuals, $ESHGs:(V,E),$ are extended to the SuperHyperResults on SuperHyperFamily, $\mathcal{NSHF}:(V,E).$
\end{proof}
%
\begin{proposition}
Let $ESHG:(V,E)$ be a strong neutrosophic SuperHyperGraph. If $S$ is a dual SuperHyperDefensive SuperHyperMatching, then $\forall v\in V\setminus S,~\exists x\in S$ such that
\begin{itemize}
\item[$(i)$]
$v\in N_s(x);$
\item[$(ii)$]
$vx\in E.$
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Consider $v\in V\setminus S.$ Since $S$ is a dual SuperHyperDefensive SuperHyperMatching,
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus S,~|N_s(v)\cap S|>|N_s(v)\cap (V\setminus S)|
\\&& v\in V\setminus S, \exists x\in S,~v\in N_s(x).
\end{eqnarray*}
$(ii).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Consider $v\in V\setminus S.$ Since $S$ is a dual SuperHyperDefensive SuperHyperMatching,
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus S,~|N_s(v)\cap S|>|N_s(v)\cap (V\setminus S)|
\\&& v\in V\setminus S, \exists x\in S:~v\in N_s(x)
\\&& v\in V\setminus S, \exists x\in S: vx\in E,~\mu(vx)=\sigma(v)\wedge\sigma(x).
\\&& v\in V\setminus S, \exists x\in S: vx\in E.
\end{eqnarray*}
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a strong neutrosophic SuperHyperGraph. If $S$ is a dual SuperHyperDefensive SuperHyperMatching, then
\begin{itemize}
\item[$(i)$]
$S$ is SuperHyperDominating set;
\item[$(ii)$]
there's $S\subseteq S'$ such that $|S'|$ is SuperHyperChromatic number.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Consider $v\in V\setminus S.$ Since $S$ is a dual SuperHyperDefensive SuperHyperMatching, either
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus S,~|N_s(v)\cap S|>|N_s(v)\cap (V\setminus S)|
\\&& v\in V\setminus S, \exists x\in S,~v\in N_s(x)
\end{eqnarray*}
or
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus S,~|N_s(v)\cap S|>|N_s(v)\cap (V\setminus S)|
\\&& v\in V\setminus S, \exists x\in S:~v\in N_s(x)
\\&& v\in V\setminus S, \exists x\in S: vx\in E,~\mu(vx)=\sigma(v)\wedge\sigma(x)
\\&& v\in V\setminus S, \exists x\in S: vx\in E.
\end{eqnarray*}
It implies $S$ is SuperHyperDominating SuperHyperSet.
\\
$(ii).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Consider $v\in V\setminus S.$ Since $S$ is a dual SuperHyperDefensive SuperHyperMatching, either
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus S,~|N_s(v)\cap S|>|N_s(v)\cap (V\setminus S)|
\\&& v\in V\setminus S, \exists x\in S,~v\in N_s(x)
\end{eqnarray*}
or
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus S,~|N_s(v)\cap S|>|N_s(v)\cap (V\setminus S)|
\\&& v\in V\setminus S, \exists x\in S:~v\in N_s(x)
\\&& v\in V\setminus S, \exists x\in S: vx\in E,~\mu(vx)=\sigma(v)\wedge\sigma(x)
\\&& v\in V\setminus S, \exists x\in S: vx\in E.
\end{eqnarray*}
Thus every SuperHyperVertex $v\in V\setminus S,$ has at least one SuperHyperNeighbor in $S.$ The only case is about the relation amid SuperHyperVertices in $S$ in the terms of SuperHyperNeighbors.
It implies there's $S\subseteq S'$ such that $|S'|$ is SuperHyperChromatic number.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a strong neutrosophic SuperHyperGraph. Then
\begin{itemize}
\item[$(i)$]
$\Gamma\leq\mathcal{O};$
\item[$(ii)$]
$\Gamma_s\leq\mathcal{O}_n.$
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Let $S=V.$
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus V,~|N_s(v)\cap V|>|N_s(v)\cap (V\setminus V)|
\\&& v\in \emptyset,~|N_s(v)\cap V|>|N_s(v)\cap \emptyset|
\\&& v\in \emptyset,~|N_s(v)\cap V|>|\emptyset|
\\&& v\in \emptyset,~|N_s(v)\cap V|>0
\end{eqnarray*}
It implies $V$ is a dual SuperHyperDefensive SuperHyperMatching. For all SuperHyperSets of SuperHyperVertices $S,~S\subseteq V.$ Thus for all SuperHyperSets of SuperHyperVertices $S,~|S|\leq |V|.$ It implies for all SuperHyperSets of SuperHyperVertices $S,~|S|\leq \mathcal{O}.$ So for all SuperHyperSets of SuperHyperVertices $S,~\Gamma\leq \mathcal{O}.$
\\
$(ii).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Let $S=V.$
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus V,~|N_s(v)\cap V|>|N_s(v)\cap (V\setminus V)|
\\&& v\in \emptyset,~|N_s(v)\cap V|>|N_s(v)\cap \emptyset|
\\&& v\in \emptyset,~|N_s(v)\cap V|>|\emptyset|
\\&& v\in \emptyset,~|N_s(v)\cap V|>0
\end{eqnarray*}
It implies $V$ is a dual SuperHyperDefensive SuperHyperMatching. For all SuperHyperSets of neutrosophic SuperHyperVertices $S,~S\subseteq V.$ Thus for all SuperHyperSets of neutrosophic SuperHyperVertices $S,~\Sigma_{s\in S}\Sigma_{i=1}^{3}\sigma_i(s)\leq \Sigma_{v\in V}\Sigma_{i=1}^{3}\sigma_i(v).$ It implies for all SuperHyperSets of neutrosophic SuperHyperVertices $S,~\Sigma_{s\in S}\Sigma_{i=1}^{3}\sigma_i(s)\leq \mathcal{O}_n.$ So for all SuperHyperSets of neutrosophic SuperHyperVertices $S,~\Gamma_s\leq \mathcal{O}_n.$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a strong neutrosophic SuperHyperGraph which is connected. Then
\begin{itemize}
\item[$(i)$]
$\Gamma\leq\mathcal{O}-1;$
\item[$(ii)$]
$\Gamma_s\leq\mathcal{O}_n-\Sigma_{i=1}^{3}\sigma_i(x).$
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Let $S=V-\{x\}$ where $x$ is arbitrary and $x\in V.$
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus V-\{x\},~|N_s(v)\cap (V-\{x\})|>|N_s(v)\cap (V\setminus (V-\{x\}))|
\\&& ~|N_s(x)\cap (V-\{x\})|>|N_s(x)\cap \{x\}|
\\&& ~|N_s(x)\cap (V-\{x\})|>|\emptyset|
\\&& ~|N_s(x)\cap (V-\{x\})|>0
\end{eqnarray*}
It implies $V-\{x\}$ is a dual SuperHyperDefensive SuperHyperMatching. For all SuperHyperSets of SuperHyperVertices $S\neq V,~S\subseteq V-\{x\}.$ Thus for all SuperHyperSets of SuperHyperVertices $S\neq V,~|S|\leq |V-\{x\}|.$ It implies for all SuperHyperSets of SuperHyperVertices $S\neq V,~|S|\leq \mathcal{O}-1.$ So for all SuperHyperSets of SuperHyperVertices $S,~\Gamma\leq \mathcal{O}-1.$
\\
$(ii).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Let $S=V-\{x\}$ where $x$ is arbitrary and $x\in V.$
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)| \\&& v\in V\setminus V-\{x\},~|N_s(v)\cap (V-\{x\})|>|N_s(v)\cap (V\setminus (V-\{x\}))|
\\&& ~|N_s(x)\cap (V-\{x\})|>|N_s(x)\cap \{x\}|
\\&& ~|N_s(x)\cap (V-\{x\})|>|\emptyset|
\\&& ~|N_s(x)\cap (V-\{x\})|>0
\end{eqnarray*}
It implies $V-\{x\}$ is a dual SuperHyperDefensive SuperHyperMatching. For all SuperHyperSets of neutrosophic SuperHyperVertices $S\neq V,~S\subseteq V-\{x\}.$ Thus for all SuperHyperSets of neutrosophic SuperHyperVertices $S\neq V,~\Sigma_{s\in S}\Sigma_{i=1}^{3}\sigma_i(s)\leq \Sigma_{v\in V-\{x\}}\Sigma_{i=1}^{3}\sigma_i(v).$ It implies for all SuperHyperSets of neutrosophic SuperHyperVertices $S\neq V,~\Sigma_{s\in S}\Sigma_{i=1}^{3}\sigma_i(s)\leq \mathcal{O}_n-\Sigma_{i=1}^{3}\sigma_i(x).$ So for all SuperHyperSets of neutrosophic SuperHyperVertices $S,~\Gamma_s\leq \mathcal{O}_n-\Sigma_{i=1}^{3}\sigma_i(x).$
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be an odd SuperHyperPath. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{v_2,v_4,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$]
$\Gamma=\lfloor\frac{n}{2}\rfloor+1$ and corresponded SuperHyperSet is $S=\{v_2,v_4,\cdots,v_{n-1}\}$;
\item[$(iii)$]
$\Gamma_s=\min\{\Sigma_{s\in S=\{v_2,v_4,\cdots,v_{n-1}\}}\Sigma_{i=1}^3\sigma_i(s), \Sigma_{s\in S=\{v_1,v_3,\cdots,v_{n-1}\}}\Sigma_{i=1}^3\sigma_i(s)\};$
\item[$(iv)$]
the SuperHyperSets $S_1=\{v_2,v_4,\cdots,v_{n-1}\}$ and $S_2=\{v_1,v_3,\cdots,v_{n-1}\}$ are only a dual SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is an odd SuperHyperPath. Let $S=\{v_2,v_4,\cdots,v_{n-1}\}$ where for all $v_i,v_j\in\{v_2,v_4,\cdots,v_{n-1}\},~v_iv_j\not\in E$ and $v_i,v_j\in V.$
\begin{eqnarray*}&&
v\in \{v_1,v_3,\cdots,v_{n}\},~|N_s(v)\cap \{v_2,v_4,\cdots.v_{n-1}\}|=2>\\&&0=|N_s(v)\cap \{v_1,v_3,\cdots,v_{n}\}|
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>\\&&0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus \{v_2,v_4,\cdots,v_{n-1}\},~|N_s(v)\cap \{v_2,v_4,\cdots.v_{n-1}\}|>\\&&|N_s(v)\cap (V\setminus\{v_2,v_4,\cdots.v_{n-1}\})|
\end{eqnarray*}
It implies $S=\{v_2,v_4,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{v_2,v_4,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_2,v_4,\cdots,v_{n-1}\},$ then
\begin{eqnarray*}&&
\exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1=1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1\not>1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $\{v_2,v_4,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_2,v_4,\cdots,v_{n-1}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_2,v_4,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\\
$(ii)$ and $(iii)$ are trivial.
\\
$(iv).$ By $(i),$ $S_1=\{v_2,v_4,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching. Thus it's enough to show that $S_2=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
Suppose $ESHG:(V,E)$ is an odd SuperHyperPath. Let $S=\{v_1,v_3,\cdots,v_{n-1}\}$ where for all $v_i,v_j\in\{v_1,v_3,\cdots,v_{n-1}\},~v_iv_j\not\in E$ and $v_i,v_j\in V.$
\begin{eqnarray*}&&
v\in \{v_2,v_4,\cdots,v_{n}\},~|N_s(v)\cap \{v_1,v_3,\cdots.v_{n-1}\}|=2>\\&&0=|N_s(v)\cap \{v_2,v_4,\cdots,v_{n}\}|
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus \{v_1,v_3,\cdots,v_{n-1}\},~|N_s(v)\cap \{v_1,v_3,\cdots.v_{n-1}\}|>\\&&|N_s(v)\cap (V\setminus\{v_1,v_3,\cdots.v_{n-1}\})|
\end{eqnarray*}
It implies $S=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{v_1,v_3,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_1,v_3,\cdots,v_{n-1}\},$ then
\begin{eqnarray*}&&
\exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1=1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1\not>1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $\{v_1,v_3,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_1,v_3,\cdots,v_{n-1}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be an even SuperHyperPath. Then
\begin{itemize}
\item[$(i)$]
the set $S=\{v_2,v_4,\cdots.v_{n}\}$ is a dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$]
$\Gamma=\lfloor\frac{n}{2}\rfloor$ and corresponded SuperHyperSets are $\{v_2,v_4,\cdots.v_n\}$ and $\{v_1,v_3,\cdots.v_{n-1}\};$
\item[$(iii)$]
$\Gamma_s=\min\{\Sigma_{s\in S=\{v_2,v_4,\cdots,v_n\}}\Sigma_{i=1}^3\sigma_i(s), \Sigma_{s\in S=\{v_1,v_3,\cdots.v_{n-1}\}}\Sigma_{i=1}^3\sigma_i(s)\};$
\item[$(iv)$]
the SuperHyperSets $S_1=\{v_2,v_4,\cdots.v_{n}\}$ and $S_2=\{v_1,v_3,\cdots.v_{n-1}\}$ are only dual SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is an even SuperHyperPath. Let $S=\{v_2,v_4,\cdots,v_{n}\}$ where for all $v_i,v_j\in\{v_2,v_4,\cdots,v_{n}\},~v_iv_j\not\in E$ and $v_i,v_j\in V.$
\begin{eqnarray*}&&
v\in \{v_1,v_3,\cdots,v_{n-1}\},~|N_s(v)\cap \{v_2,v_4,\cdots.v_{n}\}|=2>\\&&0=|N_s(v)\cap \{v_1,v_3,\cdots,v_{n-1}\}|
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>\\&&0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus \{v_2,v_4,\cdots,v_{n}\},~|N_s(v)\cap \{v_2,v_4,\cdots.v_{n}\}|>|N_s(v)\cap (V\setminus\{v_2,v_4,\cdots.v_{n}\})|
\end{eqnarray*}
It implies $S=\{v_2,v_4,\cdots,v_{n}\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{v_2,v_4,\cdots,v_{n}\}-\{v_i\}$ where $v_i\in\{v_2,v_4,\cdots,v_{n}\},$ then
\begin{eqnarray*}&&
\exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1=1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1\not>1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $\{v_2,v_4,\cdots,v_{n}\}-\{v_i\}$ where $v_i\in\{v_2,v_4,\cdots,v_{n}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_2,v_4,\cdots,v_{n}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\\
$(ii)$ and $(iii)$ are trivial.
\\
$(iv).$ By $(i),$ $S_1=\{v_2,v_4,\cdots,v_{n}\}$ is a dual SuperHyperDefensive SuperHyperMatching. Thus it's enough to show that $S_2=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
Suppose $ESHG:(V,E)$ is an even SuperHyperPath. Let $S=\{v_1,v_3,\cdots,v_{n-1}\}$ where for all $v_i,v_j\in\{v_1,v_3,\cdots,v_{n-1}\},~v_iv_j\not\in E$ and $v_i,v_j\in V.$
\begin{eqnarray*}&&
v\in \{v_2,v_4,\cdots,v_{n}\},~|N_s(v)\cap \{v_1,v_3,\cdots.v_{n-1}\}|=2>\\&&0=|N_s(v)\cap \{v_2,v_4,\cdots,v_{n}\}|
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus \{v_1,v_3,\cdots,v_{n-1}\},~|N_s(v)\cap \{v_1,v_3,\cdots.v_{n-1}\}|>\\&&|N_s(v)\cap (V\setminus\{v_1,v_3,\cdots.v_{n-1}\})|
\end{eqnarray*}
It implies $S=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{v_1,v_3,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_1,v_3,\cdots,v_{n-1}\},$ then
\begin{eqnarray*}&&
\exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1=1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1\not>1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $\{v_1,v_3,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_1,v_3,\cdots,v_{n-1}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be an even SuperHyperCycle. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{v_2,v_4,\cdots,v_{n}\}$ is a dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$]
$\Gamma=\lfloor\frac{n}{2}\rfloor$ and corresponded SuperHyperSets are $\{v_2,v_4,\cdots,v_n\}$ and $\{v_1,v_3,\cdots,v_{n-1}\};$
\item[$(iii)$]
$\Gamma_s=\min\{\Sigma_{s\in S=\{v_2,v_4,\cdots,v_n\}}\sigma(s), \Sigma_{s\in S=\{v_1,v_3,\cdots,v_{n-1}\}}\sigma(s)\};$
\item[$(iv)$]
the SuperHyperSets $S_1=\{v_2,v_4,\cdots,v_{n}\}$ and $S_2=\{v_1,v_3,\cdots,v_{n-1}\}$ are only dual SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is an even SuperHyperCycle. Let $S=\{v_2,v_4,\cdots,v_{n}\}$ where for all $v_i,v_j\in\{v_2,v_4,\cdots,v_{n}\},~v_iv_j\not\in E$ and $v_i,v_j\in V.$
\begin{eqnarray*}&&
v\in \{v_1,v_3,\cdots,v_{n-1}\},~|N_s(v)\cap \{v_2,v_4,\cdots.v_{n}\}|=2>\\&&0=|N_s(v)\cap \{v_1,v_3,\cdots,v_{n-1}\}|
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>\\&&0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus \{v_2,v_4,\cdots,v_{n}\},~|N_s(v)\cap \{v_2,v_4,\cdots.v_{n}\}|>\\&&|N_s(v)\cap (V\setminus\{v_2,v_4,\cdots.v_{n}\})|
\end{eqnarray*}
It implies $S=\{v_2,v_4,\cdots,v_{n}\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{v_2,v_4,\cdots,v_{n}\}-\{v_i\}$ where $v_i\in\{v_2,v_4,\cdots,v_{n}\},$ then
\begin{eqnarray*}&&
\exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1=1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1\not>1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $\{v_2,v_4,\cdots,v_{n}\}-\{v_i\}$ where $v_i\in\{v_2,v_4,\cdots,v_{n}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_2,v_4,\cdots,v_{n}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\\
$(ii)$ and $(iii)$ are trivial.
\\
$(iv).$ By $(i),$ $S_1=\{v_2,v_4,\cdots,v_{n}\}$ is a dual SuperHyperDefensive SuperHyperMatching. Thus it's enough to show that $S_2=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
Suppose $ESHG:(V,E)$ is an even SuperHyperCycle. Let $S=\{v_1,v_3,\cdots,v_{n-1}\}$ where for all $v_i,v_j\in\{v_1,v_3,\cdots,v_{n-1}\},~v_iv_j\not\in E$ and $v_i,v_j\in V.$
\begin{eqnarray*}&&
v\in \{v_2,v_4,\cdots,v_{n}\},~|N_s(v)\cap \{v_1,v_3,\cdots.v_{n-1}\}|=2>\\&&0=|N_s(v)\cap \{v_2,v_4,\cdots,v_{n}\}|
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus \{v_1,v_3,\cdots,v_{n-1}\},~|N_s(v)\cap \{v_1,v_3,\cdots.v_{n-1}\}|>\\&&|N_s(v)\cap (V\setminus\{v_1,v_3,\cdots.v_{n-1}\})|
\end{eqnarray*}
It implies $S=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{v_1,v_3,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_1,v_3,\cdots,v_{n-1}\},$ then
\begin{eqnarray*}&&
\exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1=1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1\not>1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $\{v_1,v_3,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_1,v_3,\cdots,v_{n-1}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be an odd SuperHyperCycle. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{v_2,v_4,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$]
$\Gamma=\lfloor\frac{n}{2}\rfloor+1$ and corresponded SuperHyperSet is $S=\{v_2,v_4,\cdots,v_{n-1}\}$;
\item[$(iii)$]
$\Gamma_s=\min\{\Sigma_{s\in S=\{v_2,v_4,\cdots.v_{n-1}\}}\Sigma_{i=1}^3\sigma_i(s), \Sigma_{s\in S=\{v_1,v_3,\cdots.v_{n-1}\}}\Sigma_{i=1}^3\sigma_i(s)\};$
\item[$(iv)$]
the SuperHyperSets $S_1=\{v_2,v_4,\cdots.v_{n-1}\}$ and $S_2=\{v_1,v_3,\cdots.v_{n-1}\}$ are only dual SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is an odd SuperHyperCycle. Let $S=\{v_2,v_4,\cdots,v_{n-1}\}$ where for all $v_i,v_j\in\{v_2,v_4,\cdots,v_{n-1}\},~v_iv_j\not\in E$ and $v_i,v_j\in V.$
\begin{eqnarray*}&&
v\in \{v_1,v_3,\cdots,v_{n}\},~|N_s(v)\cap \{v_2,v_4,\cdots.v_{n-1}\}|=2>\\&&0=|N_s(v)\cap \{v_1,v_3,\cdots,v_{n}\}|
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus \{v_2,v_4,\cdots,v_{n-1}\},~|N_s(v)\cap \{v_2,v_4,\cdots.v_{n-1}\}|>\\&&|N_s(v)\cap (V\setminus\{v_2,v_4,\cdots.v_{n-1}\})|
\end{eqnarray*}
It implies $S=\{v_2,v_4,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{v_2,v_4,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_2,v_4,\cdots,v_{n-1}\},$ then
\begin{eqnarray*}&&
\exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1=1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1\not>1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $\{v_2,v_4,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_2,v_4,\cdots,v_{n-1}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_2,v_4,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\\
$(ii)$ and $(iii)$ are trivial.
\\
$(iv).$ By $(i),$ $S_1=\{v_2,v_4,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching. Thus it's enough to show that $S_2=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
Suppose $ESHG:(V,E)$ is an odd SuperHyperCycle. Let $S=\{v_1,v_3,\cdots,v_{n-1}\}$ where for all $v_i,v_j\in\{v_1,v_3,\cdots,v_{n-1}\},~v_iv_j\not\in E$ and $v_i,v_j\in V.$
\begin{eqnarray*}&&
v\in \{v_2,v_4,\cdots,v_{n}\},~|N_s(v)\cap \{v_1,v_3,\cdots.v_{n-1}\}|=2>\\&&0=|N_s(v)\cap \{v_2,v_4,\cdots,v_{n}\}|
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus \{v_1,v_3,\cdots,v_{n-1}\},~|N_s(v)\cap \{v_1,v_3,\cdots.v_{n-1}\}|>\\&&|N_s(v)\cap (V\setminus\{v_1,v_3,\cdots.v_{n-1}\})|
\end{eqnarray*}
It implies $S=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{v_1,v_3,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_1,v_3,\cdots,v_{n-1}\},$ then
\begin{eqnarray*}&&
\exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1=1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|=1\not>1=|N_s(z)\cap (V\setminus S)|
\\&& \exists v_{i+1}\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $\{v_1,v_3,\cdots,v_{n-1}\}-\{v_i\}$ where $v_i\in\{v_1,v_3,\cdots,v_{n-1}\}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_1,v_3,\cdots,v_{n-1}\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be SuperHyperStar. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{c\}$ is a dual maximal SuperHyperMatching;
\item[$(ii)$]
$\Gamma=1;$
\item[$(iii)$]
$\Gamma_s=\Sigma_{i=1}^3\sigma_i(c);$
\item[$(iv)$]
the SuperHyperSets $S=\{c\}$ and $S\subset S'$ are only dual SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a SuperHyperStar.
\begin{eqnarray*}&&
\forall v\in V\setminus\{c\},~|N_s(v)\cap \{c\}|=1>\\&&0=|N_s(v)\cap (V\setminus\{c\})|
\forall z\in V\setminus S,~|N_s(z)\cap S|=1>\\&&0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus\{c\},~|N_s(v)\cap \{c\}|>|N_s(v)\cap (V\setminus\{c\})|
\end{eqnarray*}
It implies $S=\{c\}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S=\{c\}-\{c\}=\emptyset,$ then
\begin{eqnarray*}&&
\exists v\in V\setminus S,~|N_s(z)\cap S|=0=0=|N_s(z)\cap (V\setminus S)|
\\&& \exists v\in V\setminus S,~|N_s(z)\cap S|=0\not>0=|N_s(z)\cap (V\setminus S)|
\\&& \exists v\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $S=\{c\}-\{c\}=\emptyset$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{c\}$ is a dual SuperHyperDefensive SuperHyperMatching.
\\
$(ii)$ and $(iii)$ are trivial.
\\
$(iv).$ By $(i),$ $S=\{c\}$ is a dual SuperHyperDefensive SuperHyperMatching. Thus it's enough to show that $S\subseteq S'$ is a dual SuperHyperDefensive SuperHyperMatching.
Suppose $ESHG:(V,E)$ is a SuperHyperStar. Let $S\subseteq S'.$
\begin{eqnarray*}&&
\forall v\in V\setminus\{c\},~|N_s(v)\cap \{c\}|=1>\\&&0=|N_s(v)\cap (V\setminus\{c\})|
\forall z\in V\setminus S',~|N_s(z)\cap S'|=1>\\&&0=|N_s(z)\cap (V\setminus S')|
\\&& \forall z\in V\setminus S',~|N_s(z)\cap S'|>|N_s(z)\cap (V\setminus S')|
\end{eqnarray*}
It implies $S'\subseteq S$ is a dual SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be SuperHyperWheel. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}$ is a dual maximal SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$]
$\Gamma=|\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}|;$
\item[$(iii)$]
$\Gamma_s=\Sigma_{\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}}\Sigma_{i=1}^3\sigma_i(s);$
\item[$(iv)$]
the SuperHyperSet $\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}$ is only a dual maximal SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a SuperHyperWheel. Let $S=\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}.$ There are either
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=2>1=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\end{eqnarray*}
or
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=3>0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\end{eqnarray*}
It implies $S=\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S'=\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}-\{z\}$ where $z\in S=\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n},$ then
There are either
\begin{eqnarray*}&&
\forall z\in V\setminus S',~|N_s(z)\cap S'|=1<2=|N_s(z)\cap (V\setminus S')|
\\&& \forall z\in V\setminus S',~|N_s(z)\cap S'|<|N_s(z)\cap (V\setminus S')|
\\&& \forall z\in V\setminus S',~|N_s(z)\cap S'|\not>|N_s(z)\cap (V\setminus S')|
\end{eqnarray*}
or
\begin{eqnarray*}&&
\forall z\in V\setminus S',~|N_s(z)\cap S'|=1=1=|N_s(z)\cap (V\setminus S')|
\\&& \forall z\in V\setminus S',~|N_s(z)\cap S'|=|N_s(z)\cap (V\setminus S')|
\\&& \forall z\in V\setminus S',~|N_s(z)\cap S'|\not>|N_s(z)\cap (V\setminus S')|
\end{eqnarray*}
So $S'=\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}-\{z\}$ where $z\in S=\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_1,v_3\}\cup\{v_6,v_9\cdots,v_{i+6},\cdots,v_n\}_{i=1}^{6+3(i-1)\leq n}$ is a dual maximal SuperHyperDefensive SuperHyperMatching.
\\
$(ii),$ $(iii)$ and $(iv)$ are obvious.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be an odd SuperHyperComplete. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ is a dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$]
$\Gamma=\lfloor\frac{n}{2}\rfloor+1;$
\item[$(iii)$]
$\Gamma_s=\min\{\Sigma_{s\in S}\Sigma_{i=1}^3\sigma_i(s)\}_{S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}};$
\item[$(iv)$]
the SuperHyperSet $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ is only a dual SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is an odd SuperHyperComplete. Let $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}.$ Thus
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=\lfloor\frac{n}{2}\rfloor+1>\lfloor\frac{n}{2}\rfloor-1=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\end{eqnarray*}
It implies $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S'=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1} -\{z\}$ where $z\in S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1},$ then
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=\lfloor\frac{n}{2}\rfloor=\lfloor\frac{n}{2}\rfloor=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|
\end{eqnarray*}
So $S'=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1} -\{z\}$ where $z\in S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ is a dual SuperHyperDefensive SuperHyperMatching.
\\
$(ii),$ $(iii)$ and $(iv)$ are obvious.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be an even SuperHyperComplete. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ is a dual SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$]
$\Gamma=\lfloor\frac{n}{2}\rfloor;$
\item[$(iii)$]
$\Gamma_s=\min\{\Sigma_{s\in S}\Sigma_{i=1}^3\sigma_i(s)\}_{S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}};$
\item[$(iv)$]
the SuperHyperSet $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ is only a dual maximal SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is an even SuperHyperComplete. Let $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}.$ Thus
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=\lfloor\frac{n}{2}\rfloor>\lfloor\frac{n}{2}\rfloor-1=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
It implies $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ is a dual SuperHyperDefensive SuperHyperMatching. If $S'=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor} -\{z\}$ where $z\in S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor},$ then
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=\lfloor\frac{n}{2}\rfloor-1<\lfloor\frac{n}{2}\rfloor+1=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $S'=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor} -\{z\}$ where $z\in S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ isn't a dual SuperHyperDefensive SuperHyperMatching. It induces $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ is a dual maximal SuperHyperDefensive SuperHyperMatching.
\\
$(ii),$ $(iii)$ and $(iv)$ are obvious.
\end{proof}
\begin{proposition}
Let $\mathcal{NSHF}:(V,E)$ be a $m$-SuperHyperFamily of neutrosophic SuperHyperStars with common neutrosophic SuperHyperVertex SuperHyperSet. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{c_1,c_2,\cdots,c_m\}$ is a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF};$
\item[$(ii)$]
$\Gamma=m$ for $\mathcal{NSHF}:(V,E);$
\item[$(iii)$]
$\Gamma_s=\Sigma_{i=1}^m\Sigma_{j=1}^3\sigma_j(c_i)$ for $\mathcal{NSHF}:(V,E);$
\item[$(iv)$]
the SuperHyperSets $S=\{c_1,c_2,\cdots,c_m\}$ and $S\subset S'$ are only dual SuperHyperMatching for $\mathcal{NSHF}:(V,E).$
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a SuperHyperStar.
\begin{eqnarray*}&&
\forall v\in V\setminus\{c\},~|N_s(v)\cap \{c\}|=1>\\&&0=|N_s(v)\cap (V\setminus\{c\})|
\forall z\in V\setminus S,~|N_s(z)\cap S|=1>\\&&0=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\\&& v\in V\setminus\{c\},~|N_s(v)\cap \{c\}|>|N_s(v)\cap (V\setminus\{c\})|
\end{eqnarray*}
It implies $S=\{c_1,c_2,\cdots,c_m\}$ is a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$ If $S=\{c\}-\{c\}=\emptyset,$ then
\begin{eqnarray*}&&
\exists v\in V\setminus S,~|N_s(z)\cap S|=0=0=|N_s(z)\cap (V\setminus S)|
\\&& \exists v\in V\setminus S,~|N_s(z)\cap S|=0\not>0=|N_s(z)\cap (V\setminus S)|
\\&& \exists v\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $S=\{c\}-\{c\}=\emptyset$ isn't a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$ It induces $S=\{c_1,c_2,\cdots,c_m\}$ is a dual maximal SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$
\\
$(ii)$ and $(iii)$ are trivial.
\\
$(iv).$ By $(i),$ $S=\{c_1,c_2,\cdots,c_m\}$ is a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$ Thus it's enough to show that $S\subseteq S'$ is a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$
Suppose $ESHG:(V,E)$ is a SuperHyperStar. Let $S\subseteq S'.$
\begin{eqnarray*}&&
\forall v\in V\setminus\{c\},~|N_s(v)\cap \{c\}|=1>\\&&0=|N_s(v)\cap (V\setminus\{c\})|
\forall z\in V\setminus S',~|N_s(z)\cap S'|=1>\\&&0=|N_s(z)\cap (V\setminus S')|
\\&& \forall z\in V\setminus S',~|N_s(z)\cap S'|>|N_s(z)\cap (V\setminus S')|
\end{eqnarray*}
It implies $S'\subseteq S$ is a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$
\end{proof}
\begin{proposition}
Let $\mathcal{NSHF}:(V,E)$ be an $m$-SuperHyperFamily of odd SuperHyperComplete SuperHyperGraphs with common neutrosophic SuperHyperVertex SuperHyperSet. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ is a dual maximal SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF};$
\item[$(ii)$]
$\Gamma=\lfloor\frac{n}{2}\rfloor+1$ for $\mathcal{NSHF}:(V,E);$
\item[$(iii)$]
$\Gamma_s=\min\{\Sigma_{s\in S}\Sigma_{i=1}^3\sigma_i(s)\}_{S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}}$ for $\mathcal{NSHF}:(V,E);$
\item[$(iv)$]
the SuperHyperSets $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ are only a dual maximal SuperHyperMatching for $\mathcal{NSHF}:(V,E).$
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is odd SuperHyperComplete. Let $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}.$ Thus
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=\lfloor\frac{n}{2}\rfloor+1>\lfloor\frac{n}{2}\rfloor-1=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|
\end{eqnarray*}
It implies $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ is a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$ If $S'=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1} -\{z\}$ where $z\in S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1},$ then
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=\lfloor\frac{n}{2}\rfloor=\lfloor\frac{n}{2}\rfloor=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|
\end{eqnarray*}
So $S'=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1} -\{z\}$ where $z\in S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ isn't a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$ It induces $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor+1}$ is a dual maximal SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$
\\
$(ii),$ $(iii)$ and $(iv)$ are obvious.
\end{proof}
\begin{proposition}
Let $\mathcal{NSHF}:(V,E)$ be a $m$-SuperHyperFamily of even SuperHyperComplete SuperHyperGraphs with common neutrosophic SuperHyperVertex SuperHyperSet. Then
\begin{itemize}
\item[$(i)$]
the SuperHyperSet $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ is a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E);$
\item[$(ii)$]
$\Gamma=\lfloor\frac{n}{2}\rfloor$ for $\mathcal{NSHF}:(V,E);$
\item[$(iii)$]
$\Gamma_s=\min\{\Sigma_{s\in S}\Sigma_{i=1}^3\sigma_i(s)\}_{S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}}$ for $\mathcal{NSHF}:(V,E);$
\item[$(iv)$]
the SuperHyperSets $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ are only dual maximal SuperHyperMatching for $\mathcal{NSHF}:(V,E).$
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is even SuperHyperComplete. Let $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}.$ Thus
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=\lfloor\frac{n}{2}\rfloor>\lfloor\frac{n}{2}\rfloor-1=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
It implies $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ is a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$ If $S'=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor} -\{z\}$ where $z\in S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor},$ then
\begin{eqnarray*}&&
\forall z\in V\setminus S,~|N_s(z)\cap S|=\lfloor\frac{n}{2}\rfloor-1<\lfloor\frac{n}{2}\rfloor+1=|N_s(z)\cap (V\setminus S)|
\\&& \forall z\in V\setminus S,~|N_s(z)\cap S|\not>|N_s(z)\cap (V\setminus S)|.
\end{eqnarray*}
So $S'=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor} -\{z\}$ where $z\in S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ isn't a dual SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$ It induces $S=\{v_i\}_{i=1}^{\lfloor\frac{n}{2}\rfloor}$ is a dual maximal SuperHyperDefensive SuperHyperMatching for $\mathcal{NSHF}:(V,E).$
\\
$(ii),$ $(iii)$ and $(iv)$ are obvious.
\end{proof}
%
\begin{proposition}
Let $ESHG:(V,E)$ be a strong neutrosophic SuperHyperGraph. Then following statements hold;
\begin{itemize}
\item[$(i)$] if $s\geq t$ and a SuperHyperSet $S$ of SuperHyperVertices is an t-SuperHyperDefensive SuperHyperMatching, then $S$ is an s-SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$] if $s\leq t$ and a SuperHyperSet $S$ of SuperHyperVertices is a dual t-SuperHyperDefensive SuperHyperMatching, then $S$ is a dual s-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Consider a SuperHyperSet $S$ of SuperHyperVertices is an t-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}&&
\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<t; \\&& \forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<t\leq s;
\\&& \forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<s.
\end{eqnarray*}
Thus $S$ is an s-SuperHyperDefensive SuperHyperMatching.
\\
$(ii).$
Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Consider a SuperHyperSet $S$ of SuperHyperVertices is a dual t-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}&&
\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>t; \\&& \forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>t\geq s;
\\&& \forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>s.
\end{eqnarray*}
Thus $S$ is a dual s-SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a strong neutrosophic SuperHyperGraph. Then following statements hold;
\begin{itemize}
\item[$(i)$] if $s\geq t+2$ and a SuperHyperSet $S$ of SuperHyperVertices is an t-SuperHyperDefensive SuperHyperMatching, then $S$ is an s-SuperHyperPowerful SuperHyperMatching;
\item[$(ii)$] if $s\leq t$ and a SuperHyperSet $S$ of SuperHyperVertices is a dual t-SuperHyperDefensive SuperHyperMatching, then $S$ is a dual s-SuperHyperPowerful SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Consider a SuperHyperSet $S$ of SuperHyperVertices is an t-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<t;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<t\leq t+2\leq s;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<s.
\end{eqnarray*}
Thus $S$ is an $(t+2)-$SuperHyperDefensive SuperHyperMatching. By $S$ is an $s-$SuperHyperDefensive SuperHyperMatching and $S$ is a dual $(s+2)-$SuperHyperDefensive SuperHyperMatching, $S$ is an s-SuperHyperPowerful SuperHyperMatching.
\\
$(ii).$
Suppose $ESHG:(V,E)$ is a strong neutrosophic SuperHyperGraph. Consider a SuperHyperSet $S$ of SuperHyperVertices is a dual t-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>t;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>t\geq s>s-2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>s-2.
\end{eqnarray*}
Thus $S$ is an $(s-2)-$SuperHyperDefensive SuperHyperMatching. By $S$ is an $(s-2)-$SuperHyperDefensive SuperHyperMatching and $S$ is a dual $s-$SuperHyperDefensive SuperHyperMatching, $S$ is an $s-$SuperHyperPowerful SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ be a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph. Then following statements hold;
\begin{itemize}
\item[$(i)$] if $\forall a\in S,~|N_s(a)\cap S|< \lfloor \frac{r}{2}\rfloor+1,$ then $ESHG:(V,E)$ is an 2-SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$] if $\forall a\in V\setminus S,~|N_s(a)\cap S|> \lfloor \frac{r}{2}\rfloor+1,$ then $ESHG:(V,E)$ is a dual 2-SuperHyperDefensive SuperHyperMatching;
\item[$(iii)$] if $\forall a\in S,~|N_s(a)\cap V\setminus S|=0,$ then $ESHG:(V,E)$ is an r-SuperHyperDefensive SuperHyperMatching;
\item[$(iv)$] if $\forall a\in V\setminus S,~|N_s(a)\cap V\setminus S|=0,$ then $ESHG:(V,E)$ is a dual r-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\lfloor \frac{r}{2}\rfloor+1-(\lfloor \frac{r}{2}\rfloor-1);
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\lfloor \frac{r}{2}\rfloor+1-(\lfloor \frac{r}{2}\rfloor-1)<2;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2.
\end{eqnarray*}
Thus $S$ is an 2-SuperHyperDefensive SuperHyperMatching.
\\
$(ii).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\lfloor \frac{r}{2}\rfloor+1-(\lfloor \frac{r}{2}\rfloor-1);
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\lfloor \frac{r}{2}\rfloor+1-(\lfloor \frac{r}{2}\rfloor-1)>2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2.
\end{eqnarray*}
Thus $S$ is a dual 2-SuperHyperDefensive SuperHyperMatching.
\\
$(iii).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<r-0;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<r-0=r;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<r.
\end{eqnarray*}
Thus $S$ is an r-SuperHyperDefensive SuperHyperMatching.
\\
$(iv).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>r-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>r-0=r;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>r.
\end{eqnarray*}
Thus $S$ is a dual r-SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph. Then following statements hold;
\begin{itemize}
\item[$(i)$] $\forall a\in S,~|N_s(a)\cap S|< \lfloor \frac{r}{2}\rfloor+1$ if $ESHG:(V,E)$ is an 2-SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$] $\forall a\in V\setminus S,~|N_s(a)\cap S|> \lfloor \frac{r}{2}\rfloor+1$ if $ESHG:(V,E)$ is a dual 2-SuperHyperDefensive SuperHyperMatching;
\item[$(iii)$] $\forall a\in S,~|N_s(a)\cap V\setminus S|=0$ if $ESHG:(V,E)$ is an r-SuperHyperDefensive SuperHyperMatching;
\item[$(iv)$] $\forall a\in V\setminus S,~|N_s(a)\cap V\setminus S|=0$ if $ESHG:(V,E)$ is a dual r-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph. Then
\begin{eqnarray*}
&& \forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2;\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2=\lfloor \frac{r}{2}\rfloor+1-(\lfloor \frac{r}{2}\rfloor-1);
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\lfloor \frac{r}{2}\rfloor+1-(\lfloor \frac{r}{2}\rfloor-1);\\&&
\forall t\in S,~|N_s(t)\cap S|=\lfloor \frac{r}{2}\rfloor+1,~ |N_s(t)\cap(V\setminus S)|=\lfloor \frac{r}{2}\rfloor-1.
\end{eqnarray*}
$(ii).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and a dual 2-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|> 2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2=\lfloor \frac{r}{2}\rfloor+1-(\lfloor \frac{r}{2}\rfloor-1);
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\lfloor \frac{r}{2}\rfloor+1-(\lfloor \frac{r}{2}\rfloor-1);
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|=\lfloor \frac{r}{2}\rfloor+1,~|N_s(t)\cap (V\setminus S)=\lfloor \frac{r}{2}\rfloor-1.
\end{eqnarray*}
$(iii).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and an r-SuperHyperDefensive SuperHyperMatching.
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<r;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<r=r-0;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<r-0;
\\&&\forall t\in S,~|N_s(t)\cap S|=r,~|N_s(t)\cap (V\setminus S)|=0.
\end{eqnarray*}
$(iv).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and a dual r-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>r;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>r=r-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>r-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|=r,~|N_s(t)\cap (V\setminus S)|=0.
\end{eqnarray*}
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is a SuperHyperComplete. Then following statements hold;
\begin{itemize}
\item[$(i)$] $\forall a\in S,~|N_s(a)\cap S|< \lfloor \frac{\mathcal{O}-1}{2}\rfloor+1$ if $ESHG:(V,E)$ is an 2-SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$] $\forall a\in V\setminus S,~|N_s(a)\cap S|> \lfloor \frac{\mathcal{O}-1}{2}\rfloor+1$ if $ESHG:(V,E)$ is a dual 2-SuperHyperDefensive SuperHyperMatching;
\item[$(iii)$] $\forall a\in S,~|N_s(a)\cap V\setminus S|=0$ if $ESHG:(V,E)$ is an $(\mathcal{O}-1)$-SuperHyperDefensive SuperHyperMatching;
\item[$(iv)$] $\forall a\in V\setminus S,~|N_s(a)\cap V\setminus S|=0$ if $ESHG:(V,E)$ is a dual $(\mathcal{O}-1)$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and an 2- SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2=\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1-(\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1);
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1-(\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1);
\\&&\forall t\in S,~|N_s(t)\cap S|=\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1,~ |N_s(t)\cap(V\setminus S)|=\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1.
\end{eqnarray*}
$(ii).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and a dual 2-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|> 2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2=\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1-(\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1);
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1-(\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1);
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|=\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1,~|N_s(t)\cap (V\setminus S)=\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1.
\end{eqnarray*}
$(iii).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and an ($\mathcal{O}-1$)-SuperHyperDefensive SuperHyperMatching.
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\mathcal{O}-1;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\mathcal{O}-1=\mathcal{O}-1-0;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\mathcal{O}-1-0;
\\&&\forall t\in S,~|N_s(t)\cap S|=\mathcal{O}-1,~|N_s(t)\cap (V\setminus S)|=0.
\end{eqnarray*}
$(iv).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and a dual r-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\mathcal{O}-1;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\mathcal{O}-1=\mathcal{O}-1-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\mathcal{O}-1-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|=\mathcal{O}-1,~|N_s(t)\cap (V\setminus S)|=0.
\end{eqnarray*}
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is a SuperHyperComplete. Then following statements hold;
\begin{itemize}
\item[$(i)$] if $\forall a\in S,~|N_s(a)\cap S|< \lfloor \frac{\mathcal{O}-1}{2}\rfloor+1,$ then $ESHG:(V,E)$ is an 2-SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$] if $\forall a\in V\setminus S,~|N_s(a)\cap S|> \lfloor \frac{\mathcal{O}-1}{2}\rfloor+1,$ then $ESHG:(V,E)$ is a dual 2-SuperHyperDefensive SuperHyperMatching;
\item[$(iii)$] if $\forall a\in S,~|N_s(a)\cap V\setminus S|=0,$ then $ESHG:(V,E)$ is $(\mathcal{O}-1)$-SuperHyperDefensive SuperHyperMatching;
\item[$(iv)$] if $\forall a\in V\setminus S,~|N_s(a)\cap V\setminus S|=0,$ then $ESHG:(V,E)$ is a dual $(\mathcal{O}-1)$-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is a SuperHyperComplete. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1-(\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1);
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1-(\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1)<2;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2.
\end{eqnarray*}
Thus $S$ is an 2-SuperHyperDefensive SuperHyperMatching.
\\
$(ii).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is a SuperHyperComplete. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1-(\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1);
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\lfloor \frac{\mathcal{O}-1}{2}\rfloor+1-(\lfloor \frac{\mathcal{O}-1}{2}\rfloor-1)>2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2.
\end{eqnarray*}
Thus $S$ is a dual 2-SuperHyperDefensive SuperHyperMatching.
\\
$(iii).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is a SuperHyperComplete. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\mathcal{O}-1-0;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\mathcal{O}-1-0=\mathcal{O}-1;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<\mathcal{O}-1.
\end{eqnarray*}
Thus $S$ is an ($\mathcal{O}-1$)-SuperHyperDefensive SuperHyperMatching.
\\
$(iv).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is a SuperHyperComplete. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\mathcal{O}-1-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\mathcal{O}-1-0=\mathcal{O}-1;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>\mathcal{O}-1.
\end{eqnarray*}
Thus $S$ is a dual ($\mathcal{O}-1$)-SuperHyperDefensive SuperHyperMatching.
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is SuperHyperCycle. Then following statements hold;
\begin{itemize}
\item[$(i)$] $\forall a\in S,~|N_s(a)\cap S|< 2$ if $ESHG:(V,E))$ is an 2-SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$] $\forall a\in V\setminus S,~|N_s(a)\cap S|> 2$ if $ESHG:(V,E)$ is a dual 2-SuperHyperDefensive SuperHyperMatching;
\item[$(iii)$] $\forall a\in S,~|N_s(a)\cap V\setminus S|=0$ if $ESHG:(V,E)$ is an 2-SuperHyperDefensive SuperHyperMatching;
\item[$(iv)$] $\forall a\in V\setminus S,~|N_s(a)\cap V\setminus S|=0$ if $ESHG:(V,E)$ is a dual 2-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and $S$ is an 2-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2=2-0;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2;
\\&&\forall t\in S,~|N_s(t)\cap S|<2,~ |N_s(t)\cap(V\setminus S)|=0.
\end{eqnarray*}
$(ii).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and $S$ is a dual 2-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|> 2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2=2-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|>2,~|N_s(t)\cap (V\setminus S)=0.
\end{eqnarray*}
$(iii).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and $S$ is an 2-SuperHyperDefensive SuperHyperMatching.
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2=2-0;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2-0;
\\&&\forall t\in S,~|N_s(t)\cap S|<2,~|N_s(t)\cap (V\setminus S)|=0.
\end{eqnarray*}
$(iv).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph and $S$ is a dual r-SuperHyperDefensive SuperHyperMatching. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2=2-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|>2,~|N_s(t)\cap (V\setminus S)|=0.
\end{eqnarray*}
\end{proof}
\begin{proposition}
Let $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is SuperHyperCycle. Then following statements hold;
\begin{itemize}
\item[$(i)$] if $\forall a\in S,~|N_s(a)\cap S|< 2,$ then $ESHG:(V,E)$ is an 2-SuperHyperDefensive SuperHyperMatching;
\item[$(ii)$] if $\forall a\in V\setminus S,~|N_s(a)\cap S|> 2,$ then $ESHG:(V,E)$ is a dual 2-SuperHyperDefensive SuperHyperMatching;
\item[$(iii)$] if $\forall a\in S,~|N_s(a)\cap V\setminus S|=0,$ then $ESHG:(V,E)$ is an 2-SuperHyperDefensive SuperHyperMatching;
\item[$(iv)$] if $\forall a\in V\setminus S,~|N_s(a)\cap V\setminus S|=0,$ then $ESHG:(V,E)$ is a dual 2-SuperHyperDefensive SuperHyperMatching.
\end{itemize}
\end{proposition}
\begin{proof}
$(i).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is SuperHyperCycle. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2-0;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2-0=2;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2.
\end{eqnarray*}
Thus $S$ is an 2-SuperHyperDefensive SuperHyperMatching.
\\
$(ii).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is SuperHyperCycle. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2-0=2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2.
\end{eqnarray*}
Thus $S$ is a dual 2-SuperHyperDefensive SuperHyperMatching.
\\
$(iii).$ Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is SuperHyperCycle. Then
\begin{eqnarray*}
&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2-0;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2-0=2;
\\&&\forall t\in S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|<2.
\end{eqnarray*}
Thus $S$ is an 2-SuperHyperDefensive SuperHyperMatching.
\\
$(iv).$
Suppose $ESHG:(V,E)$ is a[an] [r-]SuperHyperUniform-strong-neutrosophic SuperHyperGraph which is SuperHyperCycle. Then
\begin{eqnarray*}
&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2-0;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2-0=2;
\\&&\forall t\in V\setminus S,~|N_s(t)\cap S|-|N_s(t)\cap (V\setminus S)|>2.
\end{eqnarray*}
Thus $S$ is a dual 2-SuperHyperDefensive SuperHyperMatching.
\end{proof}
\section{neutrosophic Applications in Cancer's neutrosophic Recognition}
The cancer is the neutrosophic disease but the neutrosophic model is going to figure out what's going on this neutrosophic phenomenon. The special neutrosophic case of this neutrosophic disease is considered and as the consequences of the model, some parameters are used. The cells are under attack of this disease but the moves of the cancer in the special region are the matter of mind. The neutrosophic recognition of the cancer could help to find some neutrosophic treatments for this neutrosophic disease.
\\
In the following, some neutrosophic steps are neutrosophic devised on this disease.
\begin{description}
\item[Step 1. (neutrosophic Definition)] The neutrosophic recognition of the cancer in the long-term neutrosophic function.
\item[Step 2. (neutrosophic Issue)] The specific region has been assigned by the neutrosophic model [it's called neutrosophic SuperHyperGraph] and the long neutrosophic cycle of the move from the cancer is identified by this research. Sometimes the move of the cancer hasn't be easily identified since there are some determinacy, indeterminacy and neutrality about the moves and the effects of the cancer on that region; this event leads us to choose another model [it's said to be neutrosophic SuperHyperGraph] to have convenient perception on what's happened and what's done.
\item[Step 3. (neutrosophic Model)]
There are some specific neutrosophic models, which are well-known and they've got the names, and some general neutrosophic models. The moves and the neutrosophic traces of the cancer on the complex tracks and between complicated groups of cells could be fantasized by a neutrosophic SuperHyperPath(-/SuperHyperCycle, SuperHyperStar, SuperHyperBipartite, SuperHyperMultipartite, SuperHyperWheel). The aim is to find either the neutrosophic SuperHyperMatching or the neutrosophic SuperHyperMatching in those neutrosophic neutrosophic SuperHyperModels.
\section{Case 1: The Initial neutrosophic Steps Toward neutrosophic SuperHyperBipartite as neutrosophic SuperHyperModel}
\item[Step 4. (neutrosophic Solution)]
In the neutrosophic Figure \eqref{119NSHGaa21aa}, the neutrosophic SuperHyperBipartite is neutrosophic highlighted and neutrosophic featured.
\begin{figure}
\includegraphics[width=100mm]{119NSHG21.png}
\caption{a neutrosophic SuperHyperBipartite Associated to the Notions of neutrosophic SuperHyperMatching}
\label{119NSHGaa21aa}
\end{figure}
\\ By using the neutrosophic Figure \eqref{119NSHGaa21aa} and the Table \eqref{119TBLaa21aa}, the neutrosophic SuperHyperBipartite is obtained.
\\
The obtained neutrosophic SuperHyperSet, by the neutrosophic Algorithm in previous neutrosophic result, of the neutrosophic SuperHyperVertices of the connected neutrosophic SuperHyperBipartite $ESHB:(V,E),$ in the neutrosophic SuperHyperModel \eqref{119NSHGaa21aa},
is the neutrosophic SuperHyperMatching.
\begin{table}
\centering
\caption{The Values of Vertices, SuperVertices, Edges, HyperEdges, and SuperHyperEdges Belong to The Neutrosophic SuperHyperBipartite}
\begin{tabular}[t]{c|c}
\hline
The Values of The Vertices & The Number of Position in Alphabet\\
\hline
The Values of The SuperVertices&The maximum Values of Its Vertices\\
\hline
The Values of The Edges&The maximum Values of Its Vertices\\
\hline
The Values of The HyperEdges&The maximum Values of Its Vertices\\
\hline
The Values of The SuperHyperEdges&The maximum Values of Its Endpoints \\
\hline
\end{tabular}
\label{119TBLaa21aa}
\end{table}
\section{Case 2: The Increasing neutrosophic Steps Toward neutrosophic SuperHyperMultipartite as neutrosophic SuperHyperModel}
\item[Step 4. (neutrosophic Solution)]
In the neutrosophic Figure \eqref{119NSHGaa22aa}, the neutrosophic SuperHyperMultipartite is neutrosophic highlighted and neutrosophic featured.
\begin{figure}
\includegraphics[width=100mm]{119NSHG22.png}
\caption{a neutrosophic SuperHyperMultipartite Associated to the Notions of neutrosophic SuperHyperMatching}
\label{119NSHGaa22aa}
\end{figure}
\\
By using the neutrosophic Figure \eqref{119NSHGaa22aa} and the Table \eqref{119TBLaa22aa}, the neutrosophic SuperHyperMultipartite is obtained.
\\
The obtained neutrosophic SuperHyperSet, by the neutrosophic Algorithm in previous result, of the neutrosophic SuperHyperVertices of the connected neutrosophic SuperHyperMultipartite $ESHM:(V,E),$ in the neutrosophic SuperHyperModel \eqref{119NSHGaa22aa}, is the neutrosophic SuperHyperMatching.
\begin{table}
\centering
\caption{The Values of Vertices, SuperVertices, Edges, HyperEdges, and SuperHyperEdges Belong to The Neutrosophic SuperHyperMultipartite}
\begin{tabular}[t]{c|c}
\hline
The Values of The Vertices & The Number of Position in Alphabet\\
\hline
The Values of The SuperVertices&The maximum Values of Its Vertices\\
\hline
The Values of The Edges&The maximum Values of Its Vertices\\
\hline
The Values of The HyperEdges&The maximum Values of Its Vertices\\
\hline
The Values of The SuperHyperEdges&The maximum Values of Its Endpoints \\
\hline
\end{tabular}
\label{119TBLaa22aa}
\end{table}
\end{description}
\section{Open Problems}
In what follows, some ``problems'' and some ``questions'' are proposed.
\\
The SuperHyperMatching and the neutrosophic SuperHyperMatching are defined on a real-world application, titled ``Cancer's Recognitions''.
\begin{question}
Which the else SuperHyperModels could be defined based on Cancer's recognitions?
\end{question}
\begin{question}
Are there some SuperHyperNotions related to SuperHyperMatching and the neutrosophic SuperHyperMatching?
\end{question}
\begin{question}
Are there some Algorithms to be defined on the SuperHyperModels to compute them?
\end{question}
\begin{question}
Which the SuperHyperNotions are related to beyond the SuperHyperMatching and the neutrosophic SuperHyperMatching?
\end{question}
\begin{problem}
The SuperHyperMatching and the neutrosophic SuperHyperMatching do a SuperHyperModel for the Cancer's recognitions and they're based on SuperHyperMatching, are there else?
\end{problem}
\begin{problem}
Which the fundamental SuperHyperNumbers are related to these SuperHyperNumbers types-results?
\end{problem}
\begin{problem}
What's the independent research based on Cancer's recognitions concerning the multiple types of SuperHyperNotions?
\end{problem}
\section{Conclusion and Closing Remarks}
In this section, concluding remarks and closing remarks are represented. The drawbacks of this research are illustrated. Some benefits and some advantages of this research are highlighted.
\\
This research uses some approaches to make neutrosophic SuperHyperGraphs more understandable. In this endeavor, two SuperHyperNotions are defined on the SuperHyperMatching. For that sake in the second definition, the main definition of the neutrosophic SuperHyperGraph is redefined on the position of the alphabets. Based on the new definition for the neutrosophic SuperHyperGraph, the new SuperHyperNotion, neutrosophic SuperHyperMatching, finds the convenient background to implement some results based on that. Some SuperHyperClasses and some neutrosophic SuperHyperClasses are the cases of this research on the modeling of the regions where are under the attacks of the cancer to recognize this disease as it's mentioned on the title ``Cancer's Recognitions''. To formalize the instances on the SuperHyperNotion, SuperHyperMatching, the new SuperHyperClasses and SuperHyperClasses, are introduced. Some general results are gathered in the section on the SuperHyperMatching and the neutrosophic SuperHyperMatching. The clarifications, instances and literature reviews have taken the whole way through. In this research, the literature reviews have fulfilled the lines containing the notions and the results. The SuperHyperGraph and neutrosophic SuperHyperGraph are the SuperHyperModels on the ``Cancer's Recognitions'' and both bases are the background of this research. Sometimes the cancer has been happened on the region, full of cells, groups of cells and embedded styles. In this segment, the SuperHyperModel proposes some SuperHyperNotions based on the connectivities of the moves of the cancer in the longest and strongest styles with the formation of the design and the architecture are formally called `` SuperHyperMatching'' in the themes of jargons and buzzwords. The prefix ``SuperHyper'' refers to the theme of the embedded styles to figure out the background for the SuperHyperNotions.
\begin{table}[ht]
\centering
\caption{A Brief Overview about Advantages and Limitations of this Research}
\label{119TBLTBL}
\begin{tabular}[t]{|c|c|}
\hline
\textcolor{black}{Advantages}&\textcolor{black}{Limitations}\\
\hline
\textcolor{black}{1. }\textcolor{red}{Redefining Neutrosophic SuperHyperGraph} &\textcolor{black}{1. }\textcolor{blue}{General Results} \\ &
\\
\textcolor{black}{2. }\textcolor{red}{ SuperHyperMatching}& \\ &
\\
\textcolor{black}{3. } \textcolor{red}{Neutrosophic SuperHyperMatching} &\textcolor{black}{2. } \textcolor{blue}{Other SuperHyperNumbers}
\\&
\\
\textcolor{black}{4. }\textcolor{red}{Modeling of Cancer's Recognitions} & \\&
\\
\textcolor{black}{5. }\textcolor{red}{SuperHyperClasses} &\textcolor{black}{3. }\textcolor{blue}{SuperHyperFamilies} \\
\hline
\end{tabular}
\end{table}
In the Table \eqref{119TBLTBL}, some limitations and advantages of this research are pointed out.
\begin{thebibliography}{595}
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\bibitem{HG2} Henry Garrett, ``\textit{Neutrosophic Co-degree and Neutrosophic Degree alongside Chromatic Numbers in the Setting of Some Classes Related to Neutrosophic Hypergraphs}'', J Curr Trends Comp Sci Res 1(1) (2022) 06-14.
\bibitem{HG3} Henry Garrett, ``\textit{Super Hyper Dominating and Super Hyper Resolving on Neutrosophic Super Hyper Graphs and Their Directions in Game Theory and Neutrosophic Super Hyper Classes}'', J Math Techniques Comput Math 1(3) (2022) 242-263.
\bibitem{HG4}
Garrett, Henry. ``\textit{0039 | Closing Numbers and Super-Closing Numbers as (Dual)Resolving and (Dual)Coloring alongside (Dual)Dominating in (Neutrosophic)n-SuperHyperGraph.}'' CERN European Organization for Nuclear Research - Zenodo, Nov. 2022. CERN European Organization for Nuclear Research, https://doi.org/10.5281/zenodo.6319942.
https://oa.mg/work/10.5281/zenodo.6319942
\bibitem{HG5}
Garrett, Henry. ``\textit{0049 | (Failed)1-Zero-Forcing Number in Neutrosophic Graphs.}'' CERN European Organization for Nuclear Research - Zenodo, Feb. 2022. CERN European Organization for Nuclear Research, https://doi.org/10.13140/rg.2.2.35241.26724.
https://oa.mg/work/10.13140/rg.2.2.35241.26724
\bibitem{HG6}
Henry Garrett, ``\textit{Neutrosophic Failed SuperHyperStable as the Survivors on the Cancer's Neutrosophic Recognition Based on Uncertainty to All Modes in Neutrosophic SuperHyperGraphs}'', Preprints 2023, 2023010240 (doi: 10.20944/preprints202301.0240.v1).
\bibitem{HG7}
Henry Garrett, ``\textit{Extremism of the Attacked Body Under the Cancer's Circumstances Where Cancer's Recognition Titled (Neutrosophic) SuperHyperGraphs}'', Preprints 2023, 2023010224, (doi: 10.20944/preprints202301.0224.v1).
\bibitem{HG8}
Henry Garrett, ``\textit{(Neutrosophic) 1-Failed SuperHyperForcing in Cancer’s Recognitions And (Neutrosophic) SuperHyperGraphs}'', Preprints 2023, 2023010105 (doi: 10.20944/preprints202301.0105.v1).
\bibitem{HG9}
Henry Garrett, ``\textit{Neutrosophic Messy-Style SuperHyperGraphs To Form Neutrosophic SuperHyperStable To Act on Cancer’s Neutrosophic Recognitions In Special ViewPoints}'', Preprints 2023, 2023010088 (doi: 10.20944/preprints202301.0088.v1).
\bibitem{HG10}
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\bibitem{HG11}
Henry Garrett, ``\textit{(Neutrosophic) SuperHyperStable on Cancer’s Recognition by Well- SuperHyperModelled (Neutrosophic) SuperHyperGraphs}'', Preprints 2023, 2023010043 (doi: 10.20944/preprints202301.0043.v1).
\bibitem{HG12} Henry Garrett, \textit{``Basic Notions on (Neutrosophic) SuperHyperForcing And (Neutrosophic) SuperHyperModeling in Cancer’s Recognitions And (Neutrosophic) SuperHyperGraphs''}, Preprints 2023, 2023010105 (doi: 10.20944/preprints202301.0105.v1).
\bibitem{HG13} Henry Garrett, \textit{``Neutrosophic Messy-Style SuperHyperGraphs To Form Neutrosophic SuperHyperStable To Act on Cancer’s Neutrosophic Recognitions In Special ViewPoints''}, Preprints 2023, 2023010088 (doi: 10.20944/preprints202301.0088.v1).
\bibitem{HG14} Henry Garrett, \textit{``(Neutrosophic) SuperHyperModeling of Cancer’s Recognitions Featuring (Neutrosophic) SuperHyperDefensive SuperHyperAlliances''}, Preprints 2022, 2022120549 (doi: 10.20944/preprints202212.0549.v1).
\bibitem{HG15} Henry Garrett, ``\textit{(Neutrosophic) SuperHyperAlliances With SuperHyperDefensive and SuperHyperOffensive Type-SuperHyperSet On (Neutrosophic) SuperHyperGraph With (Neutrosophic) SuperHyperModeling of Cancer’s Recognitions And Related (Neutrosophic) SuperHyperClasses}'', Preprints 2022, 2022120540 (doi: 10.20944/preprints202212.0540.v1).
\bibitem{HG16} Henry Garrett, ``\textit{SuperHyperGirth on SuperHyperGraph and Neutrosophic SuperHyperGraph With SuperHyperModeling of Cancer’s Recognitions}'', Preprints 2022, 2022120500 (doi: 10.20944/preprints202212.0500.v1).
\bibitem{HG17} Henry Garrett, ``\textit{Some SuperHyperDegrees and Co-SuperHyperDegrees on Neutrosophic SuperHyperGraphs and SuperHyperGraphs Alongside Applications in Cancer’s Treatments}'', Preprints 2022, 2022120324 (doi: 10.20944/preprints202212.0324.v1).
\bibitem{HG18} Henry Garrett, ``\textit{SuperHyperDominating and SuperHyperResolving on Neutrosophic SuperHyperGraphs And Their Directions in Game Theory and Neutrosophic SuperHyperClasses}'', Preprints 2022, 2022110576 (doi: 10.20944/preprints202211.0576.v1).
\bibitem{HG19} Henry Garrett,``\textit{The Focus on The Partitions Obtained By Parallel Moves In The Cancer's Extreme Recognition With Different Types of Extreme SuperHyperMatching Set and Polynomial on (Neutrosophic) SuperHyperGraphs}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.18494.15680).
\bibitem{HG20} Henry Garrett,``\textit{Extreme Failed SuperHyperClique Decides the Failures on the Cancer's Recognition in the Perfect Connections of Cancer's Attacks By SuperHyperModels Named (Neutrosophic) SuperHyperGraphs}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.32530.73922).
\bibitem{HG21} Henry Garrett,``\textit{Indeterminacy On The All Possible Connections of Cells In Front of Cancer's Attacks In The Terms of Neutrosophic Failed SuperHyperClique on Cancer's Recognition called Neutrosophic SuperHyperGraphs}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.15897.70243).
\bibitem{HG22} Henry Garrett,``\textit{Perfect Directions Toward Idealism in Cancer's Neutrosophic Recognition Forwarding Neutrosophic SuperHyperClique on Neutrosophic SuperHyperGraphs}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.30092.80004).
\bibitem{HG23} Henry Garrett,``\textit{Demonstrating Complete Connections in Every Embedded Regions and Sub-Regions in the Terms of Cancer's Recognition and (Neutrosophic) SuperHyperGraphs With (Neutrosophic) SuperHyperClique}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.23172.19849).
\bibitem{HG24} Henry Garrett,``\textit{Different Neutrosophic Types of Neutrosophic Regions titled neutrosophic Failed SuperHyperStable in Cancer’s Neutrosophic Recognition modeled in the Form of Neutrosophic SuperHyperGraphs}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.17385.36968).
\bibitem{HG25} Henry Garrett, ``\textit{Using the Tool As (Neutrosophic) Failed SuperHyperStable To SuperHyperModel Cancer's Recognition Titled (Neutrosophic) SuperHyperGraphs}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.28945.92007).
\bibitem{HG26} Henry Garrett, ``\textit{Neutrosophic Messy-Style SuperHyperGraphs To Form Neutrosophic SuperHyperStable To Act on Cancer’s Neutrosophic Recognitions In Special ViewPoints}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.11447.80803).
\bibitem{HG27} Henry Garrett, ``\textit{(Neutrosophic) SuperHyperStable on Cancer’s Recognition by Well-SuperHyperModelled (Neutrosophic) SuperHyperGraphs}'', ResearchGate 2023, (doi: 10.13140/RG.2.2.35774.77123).
\bibitem{HG28} Henry Garrett, ``\textit{Neutrosophic 1-Failed SuperHyperForcing in the SuperHyperFunction To Use Neutrosophic SuperHyperGraphs on Cancer’s Neutrosophic Recognition And Beyond}'', ResearchGate 2022, (doi: 10.13140/RG.2.2.36141.77287).
\bibitem{HG29} Henry Garrett, ``\textit{(Neutrosophic) 1-Failed SuperHyperForcing in Cancer’s Recognitions And (Neutrosophic) SuperHyperGraphs}'', ResearchGate 2022, (doi: 10.13140/RG.2.2.29430.88642).
\bibitem{HG30} Henry Garrett, ``\textit{Basic Notions on (Neutrosophic) SuperHyperForcing And (Neutrosophic) SuperHyperModeling in Cancer’s Recognitions And (Neutrosophic) SuperHyperGraphs}'', ResearchGate 2022, (doi: 10.13140/RG.2.2.11369.16487).
\bibitem{HG31} Henry Garrett, \textit{``Basic Neutrosophic Notions Concerning SuperHyperDominating and Neutrosophic SuperHyperResolving in SuperHyperGraph''}, ResearchGate 2022 (doi: 10.13140/RG.2.2.29173.86244).
\bibitem{HG32} Henry Garrett, ``\textit{Initial Material of Neutrosophic Preliminaries to Study Some Neutrosophic Notions Based on Neutrosophic SuperHyperEdge (NSHE) in Neutrosophic SuperHyperGraph (NSHG)}'', ResearchGate 2022 (doi: 10.13140/RG.2.2.25385.88160).
\bibitem{HG33} Henry Garrett, (2022). ``\textit{Beyond Neutrosophic Graphs}'', Ohio: E-publishing: Educational Publisher 1091 West 1st Ave Grandview Heights, Ohio 43212 United States. ISBN: 979-1-59973-725-6 (http://fs.unm.edu/BeyondNeutrosophicGraphs.pdf).
\bibitem{HG34} Henry Garrett, (2022). ``\textit{Neutrosophic Duality}'', Florida: GLOBAL KNOWLEDGE - Publishing House 848 Brickell Ave Ste 950 Miami, Florida 33131 United States. ISBN: 978-1-59973-743-0 (http://fs.unm.edu/NeutrosophicDuality.pdf).
\bibitem{1} F. Smarandache, ``\textit{Extension of HyperGraph to n-SuperHyperGraph and to Plithogenic n-SuperHyperGraph, and Extension of HyperAlgebra to n-ary (Classical-/Neutro-/Anti-) HyperAlgebra}'', Neutrosophic Sets and Systems 33 (2020) 290-296. (doi: 10.5281/zenodo.3783103).
\bibitem{2} M. Akram et al., ``\textit{Single-valued neutrosophic Hypergraphs}'', TWMS J. App. Eng. Math. 8 (1) (2018) 122-135.
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\bibitem{5} H.T. Nguyen and E.A. Walker, ``\textit{A First course in fuzzy logic}'', CRC Press, 2006.
\end{thebibliography}
\end{document}
Article #119
SuperHyperMatching By (R-)Definitions And Polynomials To Monitor Cancer's Recognition In Neutrosophic SuperHyperGraphs
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