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Quantum-like states on complex synchronized networks

Gregory D. Scholes

2024Proceedings of the Royal Society A Mathematical Physical and Engineering Sciences15 citationsDOIOpen Access PDF

Abstract

Recent work has exposed the idea that interesting quantum-like (QL) probability laws, including interference effects, can be manifest in classical systems. Here, we propose a model for QL states and QL bits. We suggest a way that huge, complex systems can host robust states that can process information in a QL fashion. Axioms that such states should satisfy are proposed. Specifically, it is shown that building blocks suited for QL states are networks, possibly very complex, that we defined based on <mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline" overflow="scroll"> <mml:mi>k</mml:mi> </mml:math> -regular random graphs. These networks can dynamically encode a lot of information that is distilled into the emergent states we can use for QL processing. Although the emergent states are classical, they have properties analogous to quantum states. Concrete examples of how QL functions are possible are given. The possibility of a ‘QL advantage’ for computing-type operations and the potential relevance for new kinds of function in the brain are discussed and left as open questions.

Topics & Concepts

ENCODEAxiomComputer scienceQuantumFunction (biology)Relevance (law)Quantum stateState (computer science)Theoretical computer scienceQuantum computerProcess (computing)AlgorithmMathematicsPhysicsQuantum mechanicsProgramming languageEvolutionary biologyGeometryChemistryLawBiochemistryBiologyGenePolitical scienceNeural dynamics and brain functionQuantum Mechanics and ApplicationsQuantum Information and Cryptography
Quantum-like states on complex synchronized networks | Litcius