Non-markovian momentum computing: thermodynamically efficient and computation universal
Practical, useful computations are instantiated via physical processes. Information must be stored and updated within a system’s configurations, whose energetics determine a computation’s cost. To describe thermodynamic and biological information processing, a growing body of results embraces rate e...
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sg-ntu-dr.10356-1607052023-02-28T20:07:12Z Non-markovian momentum computing: thermodynamically efficient and computation universal Ray, Kyle J. Boyd, Alexander B. Wimsatt, Gregory W. Crutchfield, James P. School of Physical and Mathematical Sciences Complexity Institute Science::Physics Continuous-Time Natural Computing Practical, useful computations are instantiated via physical processes. Information must be stored and updated within a system’s configurations, whose energetics determine a computation’s cost. To describe thermodynamic and biological information processing, a growing body of results embraces rate equations as the underlying mechanics of computation. Strictly applying these continuous-time stochastic Markov dynamics, however, precludes a universe of natural computing. Within this framework, operations as simple as a NOT gate (flipping a bit) and swapping two bits, and swapping bits are inaccessible. We show that expanding the toolset to continuous time hidden Markov dynamics substantially removes the constraints, by allowing information to be stored in a system’s latent states. We demonstrate this by simulating computations that are impossible to implement without hidden states. We design and analyze a thermodynamically costless bit flip, providing a counterexample to rate equation modeling. We generalize this to a costless Fredkin gate—a key operation in reversible computing that is Turing complete (computation universal). Going beyond rate-equation dynamics is not only possible but also necessary if stochastic thermodynamics is to become part of the paradigm for physical information processing. Published version This material is based on work supported by, or in part by, FQXi Grant No. FQXi-RFP-IPW-1902, the Templeton World Charity Foundation Power of Information fellowship TWCF0337, the US Army Research Laboratory, and the US Army Research Office under Grants No. W911NF-18-1-0028 and No. W911NF-21-100048. 2022-08-01T05:44:24Z 2022-08-01T05:44:24Z 2021 Journal Article Ray, K. J., Boyd, A. B., Wimsatt, G. W. & Crutchfield, J. P. (2021). Non-markovian momentum computing: thermodynamically efficient and computation universal. Physical Review Research, 3(2), 023164-1-023164-7. https://dx.doi.org/10.1103/PhysRevResearch.3.023164 2643-1564 https://hdl.handle.net/10356/160705 10.1103/PhysRevResearch.3.023164 2-s2.0-85115899281 2 3 023164-1 023164-7 en Physical Review Research © 2021 The Authors. Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article’s title, journal citation, and DOI. application/pdf |
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Science::Physics Continuous-Time Natural Computing Ray, Kyle J. Boyd, Alexander B. Wimsatt, Gregory W. Crutchfield, James P. Non-markovian momentum computing: thermodynamically efficient and computation universal |
| description |
Practical, useful computations are instantiated via physical processes. Information must be stored and updated within a system’s configurations, whose energetics determine a computation’s cost. To describe thermodynamic and biological information processing, a growing body of results embraces rate equations as the underlying mechanics of computation. Strictly applying these continuous-time stochastic Markov dynamics, however, precludes a universe of natural computing. Within this framework, operations as simple as a NOT gate (flipping a bit) and swapping two bits, and swapping bits are inaccessible. We show that expanding the toolset to continuous time hidden Markov dynamics substantially removes the constraints, by allowing information to be stored in a system’s latent states. We demonstrate this by simulating computations that are impossible to implement without hidden states. We design and analyze a thermodynamically costless bit flip, providing a counterexample to rate equation modeling. We generalize this to a costless Fredkin gate—a key operation in reversible computing that is Turing complete (computation universal). Going beyond rate-equation dynamics is not only possible but also necessary if stochastic thermodynamics is to become part of the paradigm for physical information processing. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Ray, Kyle J. Boyd, Alexander B. Wimsatt, Gregory W. Crutchfield, James P. |
| format |
Article |
| author |
Ray, Kyle J. Boyd, Alexander B. Wimsatt, Gregory W. Crutchfield, James P. |
| author_sort |
Ray, Kyle J. |
| title |
Non-markovian momentum computing: thermodynamically efficient and computation universal |
| title_short |
Non-markovian momentum computing: thermodynamically efficient and computation universal |
| title_full |
Non-markovian momentum computing: thermodynamically efficient and computation universal |
| title_fullStr |
Non-markovian momentum computing: thermodynamically efficient and computation universal |
| title_full_unstemmed |
Non-markovian momentum computing: thermodynamically efficient and computation universal |
| title_sort |
non-markovian momentum computing: thermodynamically efficient and computation universal |
| publishDate |
2022 |
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https://hdl.handle.net/10356/160705 |
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1759857733865046016 |