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The free energy principle induces neuromorphic development

Chris Fields, Karl Friston, James F. Glazebrook, Michael Levin, Antonino Marcianò

2022Neuromorphic Computing and Engineering23 citationsDOIOpen Access PDF

Abstract

Abstract We show how any finite physical system with morphological, i.e. three-dimensional embedding or shape, degrees of freedom and locally limited free energy will, under the constraints of the free energy principle, evolve over time towards a neuromorphic morphology that supports hierarchical computations in which each ‘level’ of the hierarchy enacts a coarse-graining of its inputs, and dually, a fine-graining of its outputs. Such hierarchies occur throughout biology, from the architectures of intracellular signal transduction pathways to the large-scale organization of perception and action cycles in the mammalian brain. The close formal connections between cone-cocone diagrams (CCCD) as models of quantum reference frames on the one hand, and between CCCDs and topological quantum field theories on the other, allow the representation of such computations in the fully-general quantum-computational framework of topological quantum neural networks.

Topics & Concepts

GranularityEmbeddingHierarchyTheoretical computer scienceNeuromorphic engineeringComputer scienceComputationQuantumDegrees of freedom (physics and chemistry)Topology (electrical circuits)Representation (politics)Quantum computerAction (physics)PhysicsMathematicsArtificial intelligenceArtificial neural networkAlgorithmQuantum mechanicsOperating systemPolitical scienceMarket economyPoliticsEconomicsCombinatoricsLawNeural dynamics and brain functionPhotoreceptor and optogenetics researchPlant and Biological Electrophysiology Studies