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Toward a formal theory for computing machines made out of whatever physics offers

Herbert Jaeger, Beatriz Noheda, Wilfred G. van der Wiel

2023Nature Communications69 citationsDOIOpen Access PDF

Abstract

Approaching limitations of digital computing technologies have spurred research in neuromorphic and other unconventional approaches to computing. Here we argue that if we want to engineer unconventional computing systems in a systematic way, we need guidance from a formal theory that is different from the classical symbolic-algorithmic Turing machine theory. We propose a general strategy for developing such a theory, and within that general view, a specific approach that we call fluent computing. In contrast to Turing, who modeled computing processes from a top-down perspective as symbolic reasoning, we adopt the scientific paradigm of physics and model physical computing systems bottom-up by formalizing what can ultimately be measured in a physical computing system. This leads to an understanding of computing as the structuring of processes, while classical models of computing systems describe the processing of structures.

Topics & Concepts

Computer scienceUnconventional computingTuring machineStructuringNeuromorphic engineeringPerspective (graphical)Theoretical computer scienceSuper-recursive algorithmArtificial intelligenceUniversal Turing machineProgramming languageComputationDistributed computingArtificial neural networkEconomicsFinanceAdvanced Memory and Neural ComputingCellular Automata and ApplicationsComputability, Logic, AI Algorithms
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