Inferring microscopic kinetic rates from stationary state distributions

Purushottam D. Dixit; Ken A. Dill

doi:10.1021/ct5001389

Inferring microscopic kinetic rates from stationary state distributions

Purushottam D. Dixit
, Ken A. Dill

Laufer Center for Physical and Quantitative Biology

Columbia University

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

28 Scopus citations

Abstract

We present a principled approach for estimating the matrix of microscopic transition probabilities among states of a Markov process, given only its stationary state population distribution and a single average global kinetic observable. We adapt Maximum Caliber, a variational principle in which the path entropy is maximized over the distribution of all possible trajectories, subject to basic kinetic constraints and some average dynamical observables. We illustrate the method by computing the solvation dynamics of water molecules from molecular dynamics trajectories.

Original language	English
Pages (from-to)	3002-3005
Number of pages	4
Journal	Journal of Chemical Theory and Computation
Volume	10
Issue number	8
DOIs	https://doi.org/10.1021/ct5001389
State	Published - Aug 12 2014

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10.1021/ct5001389

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title = "Inferring microscopic kinetic rates from stationary state distributions",

abstract = "We present a principled approach for estimating the matrix of microscopic transition probabilities among states of a Markov process, given only its stationary state population distribution and a single average global kinetic observable. We adapt Maximum Caliber, a variational principle in which the path entropy is maximized over the distribution of all possible trajectories, subject to basic kinetic constraints and some average dynamical observables. We illustrate the method by computing the solvation dynamics of water molecules from molecular dynamics trajectories.",

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AU - Dill, Ken A.

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N2 - We present a principled approach for estimating the matrix of microscopic transition probabilities among states of a Markov process, given only its stationary state population distribution and a single average global kinetic observable. We adapt Maximum Caliber, a variational principle in which the path entropy is maximized over the distribution of all possible trajectories, subject to basic kinetic constraints and some average dynamical observables. We illustrate the method by computing the solvation dynamics of water molecules from molecular dynamics trajectories.

AB - We present a principled approach for estimating the matrix of microscopic transition probabilities among states of a Markov process, given only its stationary state population distribution and a single average global kinetic observable. We adapt Maximum Caliber, a variational principle in which the path entropy is maximized over the distribution of all possible trajectories, subject to basic kinetic constraints and some average dynamical observables. We illustrate the method by computing the solvation dynamics of water molecules from molecular dynamics trajectories.

UR - https://www.scopus.com/pages/publications/84906240969

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DO - 10.1021/ct5001389

M3 - Article

AN - SCOPUS:84906240969

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SP - 3002

EP - 3005

JO - Journal of Chemical Theory and Computation

JF - Journal of Chemical Theory and Computation

IS - 8

ER -

Inferring microscopic kinetic rates from stationary state distributions

Abstract

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