English

Optimal Work Extraction and the Minimum Description Length Principle

Statistical Mechanics 2020-09-10 v3 Information Theory math.IT

Abstract

We discuss work extraction from classical information engines (e.g., Szil\'ard) with NN-particles, qq partitions, and initial arbitrary non-equilibrium states. In particular, we focus on their {\em optimal} behaviour, which includes the measurement of a set of quantities Φ\Phi with a feedback protocol that extracts the maximal average amount of work. We show that the optimal non-equilibrium state to which the engine should be driven before the measurement is given by the normalised maximum-likelihood probability distribution of a statistical model that admits Φ\Phi as sufficient statistics. Furthermore, we show that the minimax universal code redundancy R\mathcal{R}^* associated to this model, provides an upper bound to the work that the demon can extract on average from the cycle, in units of kBTk_{\rm B}T. We also find that, in the limit of NN large, the maximum average extracted work cannot exceed H[Φ]/2H[\Phi]/2, i.e. one half times the Shannon entropy of the measurement. Our results establish a connection between optimal work extraction in stochastic thermodynamics and optimal universal data compression, providing design principles for optimal information engines. In particular, they suggest that: (i) optimal coding is thermodynamically efficient, and (ii) it is essential to drive the system into a critical state in order to achieve optimal performance.

Keywords

Cite

@article{arxiv.2006.04544,
  title  = {Optimal Work Extraction and the Minimum Description Length Principle},
  author = {Léo Touzo and Matteo Marsili and Neri Merhav and Édgar Roldán},
  journal= {arXiv preprint arXiv:2006.04544},
  year   = {2020}
}

Comments

26 pages, 5 figures. To appear in JSTAT

R2 v1 2026-06-23T16:08:37.484Z