Published January 19, 2022 | Version v1
Journal article Open

A duality theoretic view on limits of finite structures: Extended version

  • 1. CNRS and Université Côte d'Azur, Nice, France
  • 2. Department of Computer Science and Technology, University of Cambridge, UK
  • 3. Department of Computer Science, University of Oxford, UK

Description

A systematic theory of structural limits for finite models has been developed by Nesetril and Ossona de Mendez. It is based on the insight that the collection of finite structures can be embedded, via a map they call the Stone pairing, in a space of measures, where the desired limits can be computed. We show that a closely related but finer grained space of (finitely additive) measures arises -- via Stone-Priestley duality and the notion of types from model theory -- by enriching the expressive power of first-order logic with certain "probabilistic operators". We provide a sound and complete calculus for this extended logic and expose the functorial nature of this construction. The consequences are two-fold. On the one hand, we identify the logical gist of the theory of structural limits. On the other hand, our construction shows that the duality theoretic variant of the Stone pairing captures the adding of a layer of quantifiers, thus making a strong link to recent work on semiring quantifiers in logic on words. In the process, we identify the model theoretic notion of types as the unifying concept behind this link. These results contribute to bridging the strands of logic in computer science which focus on semantics and on more algorithmic and complexity related areas, respectively.

Files

Gehrke, Jakl, Reggio - A duality theoretic view on limits of finite structures (Extended Version).pdf

Additional details

Funding

D-FINED – Duality for Finite Models: Relating Structure and Power 837724
European Commission
Resources and co-resources: a junction between semantics and descriptive complexity EP/T007257/1
UK Research and Innovation
DuaLL – Duality in Formal Languages and Logic - a unifying approach to complexity and semantics 670624
European Commission