English

Maximum Caliber Inference and the Stochastic Ising Model

Statistical Mechanics 2016-12-28 v1

Abstract

We investigate the maximum caliber variational principle as an inference algorithm used to predict dynamical properties of complex nonequilibrium, stationary, statistical systems in the presence of incomplete information. Specifically, we maximize the path entropy over discrete time step trajectories subject to normalization, stationarity, and detailed balance constraints together with a path-dependent dynamical information constraint reflecting a given average global behavior of the complex system. A general expression for the transition probability values associated with the stationary random Markov processes describing the nonequilibrium stationary system is computed. By virtue of our analysis, we uncover that a convenient choice of the dynamical information constraint together with a perturbative asymptotic expansion with respect to its corresponding Lagrange multiplier of the general expression for the transition probability leads to a formal overlap with the well-known Glauber hyperbolic tangent rule for the transition probability for the stochastic Ising model in the limit of very high temperatures of the heat reservoir.

Keywords

Cite

@article{arxiv.1612.06356,
  title  = {Maximum Caliber Inference and the Stochastic Ising Model},
  author = {Carlo Cafaro and Sean Alan Ali},
  journal= {arXiv preprint arXiv:1612.06356},
  year   = {2016}
}

Comments

21 pages, no figures

R2 v1 2026-06-22T17:28:39.621Z