Learning Without Neurons in Physical Systems
Learning is traditionally studied in biological or computational systems. The power of learning frameworks in solving hard inverse problems provides an appealing case for the development of physical learning in which physical systems adopt desirable properties on their own without computational design. It was recently realized that large classes of physical systems can physically learn through local learning rules, autonomously adapting their parameters in response to observed examples of use. We review recent work in the emerging field of physical learning, describing theoretical and experimental advances in areas ranging from molecular self-assembly to flow networks and mechanical materials. Physical learning machines provide multiple practical advantages over computer designed ones, in particular by not requiring an accurate model of the system, and their ability to autonomously adapt to changing needs over time. As theoretical constructs, physical learning machines afford a novel perspective on how physical constraints modify abstract learning theory.
Top-30
Journals
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Physical Review E
5 publications, 7.25%
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Physical Review Letters
5 publications, 7.25%
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Nature
3 publications, 4.35%
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Proceedings of the National Academy of Sciences of the United States of America
3 publications, 4.35%
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Physical Review Applied
3 publications, 4.35%
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Physical Review Research
3 publications, 4.35%
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PRX Life
2 publications, 2.9%
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Soft Matter
2 publications, 2.9%
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Nature Communications
2 publications, 2.9%
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Journal of Chemical Physics
2 publications, 2.9%
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bioRxiv
1 publication, 1.45%
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Journal of the Optical Society of America B: Optical Physics
1 publication, 1.45%
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Journal of Physics Materials
1 publication, 1.45%
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Nature Reviews Chemistry
1 publication, 1.45%
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APL Machine Learning
1 publication, 1.45%
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Chemical Reviews
1 publication, 1.45%
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Advanced Science
1 publication, 1.45%
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Machine Learning: Science and Technology
1 publication, 1.45%
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Materials and Design
1 publication, 1.45%
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Science China: Physics, Mechanics and Astronomy
1 publication, 1.45%
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Neuromorphic Computing and Engineering
1 publication, 1.45%
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Current Biology
1 publication, 1.45%
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Scientific Reports
1 publication, 1.45%
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npj Systems Biology and Applications
1 publication, 1.45%
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ChemSystemsChem
1 publication, 1.45%
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Journal of the Royal Society Interface
1 publication, 1.45%
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Advanced Intelligent Systems
1 publication, 1.45%
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Cell
1 publication, 1.45%
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Annual Review of Condensed Matter Physics
1 publication, 1.45%
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Publishers
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American Physical Society (APS)
19 publications, 27.54%
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Springer Nature
9 publications, 13.04%
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Cold Spring Harbor Laboratory
7 publications, 10.14%
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AIP Publishing
5 publications, 7.25%
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IOP Publishing
4 publications, 5.8%
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Wiley
4 publications, 5.8%
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Elsevier
4 publications, 5.8%
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Institute of Electrical and Electronics Engineers (IEEE)
4 publications, 5.8%
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Proceedings of the National Academy of Sciences (PNAS)
3 publications, 4.35%
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Royal Society of Chemistry (RSC)
2 publications, 2.9%
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The Royal Society
2 publications, 2.9%
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Stichting SciPost
2 publications, 2.9%
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Optica Publishing Group
1 publication, 1.45%
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American Chemical Society (ACS)
1 publication, 1.45%
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Science in China Press
1 publication, 1.45%
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Annual Reviews
1 publication, 1.45%
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- We do not take into account publications without a DOI.
- Statistics recalculated weekly.