General limit to thermodynamic annealing performance

Yutong Luo; Yi-Zheng Zhen; Xiangjing Liu; Daniel Ebler; Oscar Dahlsten

doi:10.1103/PhysRevE.108.L052105

General limit to thermodynamic annealing performance

Yutong Luo, Yi-Zheng Zhen, Xiangjing Liu, Daniel Ebler, Oscar Dahlsten

Department of Physics

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

1 Citation (Scopus)

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Abstract

Annealing has proven highly successful in finding minima in a cost landscape. Yet, depending on the landscape, systems often converge towards local minima rather than global ones. In this Letter, we analyze the conditions for which annealing is approximately successful in finite time. We connect annealing to stochastic thermodynamics to derive a general bound on the distance between the system state at the end of the annealing and the ground state of the landscape. This distance depends on the amount of state updates of the system and the accumulation of nonequilibrium energy, two protocol and energy landscape-dependent quantities which we show are in a trade-off relation. We describe how to bound the two quantities both analytically and physically. This offers a general approach to assess the performance of annealing from accessible parameters, both for simulated and physical implementations. © 2023 American Physical Society.

Original language	English
Article number	L052105
Journal	Physical Review E
Volume	108
Issue number	5
Online published	Nov 2023
DOIs	https://doi.org/10.1103/PhysRevE.108.L052105
Publication status	Published - Nov 2023

Publisher's Copyright Statement

COPYRIGHT TERMS OF DEPOSITED FINAL PUBLISHED VERSION FILE: Luo, Y., Zhen, Y-Z., Liu, X., Ebler, D., & Dahlsten, O. (2023). General limit to thermodynamic annealing performance. Physical Review E, 108(5), Article L052105. https://doi.org/10.1103/PhysRevE.108.L052105. The copyright of this article is owned by American Physical Society.

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title = "General limit to thermodynamic annealing performance",

abstract = "Annealing has proven highly successful in finding minima in a cost landscape. Yet, depending on the landscape, systems often converge towards local minima rather than global ones. In this Letter, we analyze the conditions for which annealing is approximately successful in finite time. We connect annealing to stochastic thermodynamics to derive a general bound on the distance between the system state at the end of the annealing and the ground state of the landscape. This distance depends on the amount of state updates of the system and the accumulation of nonequilibrium energy, two protocol and energy landscape-dependent quantities which we show are in a trade-off relation. We describe how to bound the two quantities both analytically and physically. This offers a general approach to assess the performance of annealing from accessible parameters, both for simulated and physical implementations. {\textcopyright} 2023 American Physical Society.",

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General limit to thermodynamic annealing performance

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