Thermodynamic machine learning through maximum work production
Adaptive systems—such as a biological organism gaining survival advantage, an autonomous robot executing a functional task, or a motor protein transporting intracellular nutrients—must somehow embody relevant regularities and stochasticity in their environments to take full advantage of thermodynami...
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sg-ntu-dr.10356-1707662023-10-09T15:34:57Z Thermodynamic machine learning through maximum work production Boyd, Alexander B. Crutchfield, James P. Gu, Mile School of Physical and Mathematical Sciences Science::Physics Non Equilibrium Thermodynamics Maximum Likelihood Estimation Adaptive systems—such as a biological organism gaining survival advantage, an autonomous robot executing a functional task, or a motor protein transporting intracellular nutrients—must somehow embody relevant regularities and stochasticity in their environments to take full advantage of thermodynamic resources. Analogously, but in a purely computational realm, machine learning algorithms estimate models to capture predictable structure and identify irrelevant noise in training data. This happens through optimization of performance metrics, such as model likelihood. If such learning is physically implemented, is there a sense in which computational models estimated through machine learning are physically preferred? We introduce the thermodynamic principle that work production is the most relevant performance measure for an adaptive physical agent and compare the results to the maximum-likelihood principle that guides machine learning. Within the class of physical agents that most efficiently harvest energy from their environment, we demonstrate that an efficient agent’s model explicitly determines its architecture and how much useful work it harvests from the environment. We then show that selecting the maximum-work agent for given environmental data corresponds to finding the maximum-likelihood model. This establishes an equivalence between nonequilibrium thermodynamics and dynamic learning. In this way, work maximization emerges as an organizing principle that underlies learning in adaptive thermodynamic systems. Ministry of Education (MOE) National Research Foundation (NRF) Published version This project is supported by the is supported by NationalResearch Foundation (NRF) Singapore bunder its NRFF Fellow program (Award No. NRF-NRFF2016-02), Singapore Ministry of Education Tier 1 Grant Nos. RG146/20 and RG77/22, Singapore Ministry of Education Tier 2 Grant T2EP50221-0014, Grant Nos. FQXi-RFP-IPW-1902 and FQXi-RFP-1809 from the Foundational Questions Institute and Fetzer Franklin Fund (a donor-advised fund of Silicon Valley Community Foundation), the Templeton World Charity Foundation Power of Information fellowship TWCF0337, TWCF0560 and TWCF0570, and US Army Research Laboratory and the US Army Research Office under Grants W911NF-18-1-0028 and W911NF-21-1-0048. 2023-10-09T02:20:09Z 2023-10-09T02:20:09Z 2022 Journal Article Boyd, A. B., Crutchfield, J. P. & Gu, M. (2022). Thermodynamic machine learning through maximum work production. New Journal of Physics, 24(8), 083040-. https://dx.doi.org/10.1088/1367-2630/ac4309 1367-2630 https://hdl.handle.net/10356/170766 10.1088/1367-2630/ac4309 2-s2.0-85138489123 8 24 083040 en NRF-NRFF2016-02 RG146/20 RG77/22 T2EP50221-0014 New Journal of Physics © 2022 The Author(s). This is an open-access article distributed under the terms of Creative Commons License. application/pdf |
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Science::Physics Non Equilibrium Thermodynamics Maximum Likelihood Estimation Boyd, Alexander B. Crutchfield, James P. Gu, Mile Thermodynamic machine learning through maximum work production |
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Adaptive systems—such as a biological organism gaining survival advantage, an autonomous robot executing a functional task, or a motor protein transporting intracellular nutrients—must somehow embody relevant regularities and stochasticity in their environments to take full advantage of thermodynamic resources. Analogously, but in a purely computational realm, machine learning algorithms estimate models to capture predictable structure and identify irrelevant noise in training data. This happens through optimization of performance metrics, such as model likelihood. If such learning is physically implemented, is there a sense in which computational models estimated through machine learning are physically preferred? We introduce the thermodynamic principle that work production is the most relevant performance measure for an adaptive physical agent and compare the results to the maximum-likelihood principle that guides machine learning. Within the class of physical agents that most efficiently harvest energy from their environment, we demonstrate that an efficient agent’s model explicitly determines its architecture and how much useful work it harvests from the environment. We then show that selecting the maximum-work agent for given environmental data corresponds to finding the maximum-likelihood model. This establishes an equivalence between nonequilibrium thermodynamics and dynamic learning. In this way, work maximization emerges as an organizing principle that underlies learning in adaptive thermodynamic systems. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Boyd, Alexander B. Crutchfield, James P. Gu, Mile |
| format |
Article |
| author |
Boyd, Alexander B. Crutchfield, James P. Gu, Mile |
| author_sort |
Boyd, Alexander B. |
| title |
Thermodynamic machine learning through maximum work production |
| title_short |
Thermodynamic machine learning through maximum work production |
| title_full |
Thermodynamic machine learning through maximum work production |
| title_fullStr |
Thermodynamic machine learning through maximum work production |
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Thermodynamic machine learning through maximum work production |
| title_sort |
thermodynamic machine learning through maximum work production |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/170766 |
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