Exactly solvable statistical physics models for large neuronal populations

Christopher W. Lynn; Qiwei Yu; Rich Pang; William Bialek; Stephanie E. Palmer

doi:10.1103/PhysRevResearch.7.L022039

Exactly solvable statistical physics models for large neuronal populations

Christopher W. Lynn
, Qiwei Yu
, Rich Pang
, William Bialek
, Stephanie E. Palmer

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Maximum-entropy methods provide a principled path connecting measurements of neural activity directly to statistical physics models, and this approach has been successful for populations of N∼100 neurons. As N increases in new experiments, we enter an undersampled regime where we have to choose which observables should be constrained in the maximum-entropy construction. The best choice is the one that provides the greatest reduction in entropy, defining a "minimax entropy"principle. This principle becomes tractable if we restrict attention to correlations among pairs of neurons that link together into a tree; we can find the best tree efficiently, and the underlying statistical physics models are exactly solved. We use this approach to analyze experiments on N∼1500 neurons in the mouse hippocampus, and we find that the resulting model captures key features of collective activity in the network.

Original language	English (US)
Article number	L022039
Journal	Physical Review Research
Volume	7
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevResearch.7.L022039
State	Published - Apr 2025

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevResearch.7.L022039

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title = "Exactly solvable statistical physics models for large neuronal populations",

abstract = "Maximum-entropy methods provide a principled path connecting measurements of neural activity directly to statistical physics models, and this approach has been successful for populations of N∼100 neurons. As N increases in new experiments, we enter an undersampled regime where we have to choose which observables should be constrained in the maximum-entropy construction. The best choice is the one that provides the greatest reduction in entropy, defining a {"}minimax entropy{"}principle. This principle becomes tractable if we restrict attention to correlations among pairs of neurons that link together into a tree; we can find the best tree efficiently, and the underlying statistical physics models are exactly solved. We use this approach to analyze experiments on N∼1500 neurons in the mouse hippocampus, and we find that the resulting model captures key features of collective activity in the network.",

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AU - Yu, Qiwei

AU - Pang, Rich

AU - Bialek, William

AU - Palmer, Stephanie E.

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AB - Maximum-entropy methods provide a principled path connecting measurements of neural activity directly to statistical physics models, and this approach has been successful for populations of N∼100 neurons. As N increases in new experiments, we enter an undersampled regime where we have to choose which observables should be constrained in the maximum-entropy construction. The best choice is the one that provides the greatest reduction in entropy, defining a "minimax entropy"principle. This principle becomes tractable if we restrict attention to correlations among pairs of neurons that link together into a tree; we can find the best tree efficiently, and the underlying statistical physics models are exactly solved. We use this approach to analyze experiments on N∼1500 neurons in the mouse hippocampus, and we find that the resulting model captures key features of collective activity in the network.

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Exactly solvable statistical physics models for large neuronal populations

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