Dynamic Reasoning intelligence Near Quantum
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Dynamic Reasoning Intelligence Near Quantum (DRINQ)
Function: Simulates parallel logic paths, filters them by stability, and selects the best outcome.
Problem it solves: Makes complex decisions when outcomes are uncertain or evolving.
Abstract: Predicting Quantum Measurement Outcomes via the Stone Loop in DRINQ
This work presents a novel quantum-inspired mechanism for predicting measurement outcomes within the DRINQ (Dynamic Reasoning Intelligence Near Quantum) framework using the geometric and symbolic construct known as the Stone Loop. The loops path length, derived from tilt, twist, and rotational parameters, functions as a recursive proxy for action in Feynmans path integral approach. Each Stone Loop trajectory is treated as a candidate quantum logic path and is assigned a complex amplitude based on its geometric length. The DRINQ system then aggregates these amplitudes and applies the Born Rule to determine the probability of a given outcome.
Measurement collapse is guided not only by amplitude interference, but also by DRINQs recursive constraint logic, which filters unstable or incoherent paths using derivative and epsilon thresholds. The system collapses to a stable outcome when a constraint fixes one variable, echoing the quantum principle that measurement forces determinacy. This hybrid approach fuses symbolic recursion, logic evaluation, and near-quantum path dynamics to enable predictive, coherent, and stable artificial reasoning.
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- Alternative title
- Parameter based quantum collapse mapping