热力学线性代数

Maxwell Aifer, Kaelan Donatella, Max Hunter Gordon, Samuel Duffield, Thomas Ahle, Daniel Simpson, Gavin Crooks, Patrick J. Coles
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引用次数: 0

摘要

线性代数是工程、科学和机器学习中许多算法的核心;因此,加速线性代数将产生巨大的经济影响。为此,有人提出了量子计算,但其资源需求远远超出了目前的技术能力。我们考虑基于经典热力学的另一种物理计算范式,为加速线性代数提供一种近期方法。乍一看,热力学和线性代数似乎是互不相关的领域。在这里,我们将解决线性代数问题与从耦合谐振子系统的热力学平衡分布中采样联系起来。我们介绍了求解线性方程组、计算矩阵倒数和计算矩阵行列式的简单热力学算法。在合理的假设条件下,我们严格地确定了我们算法相对于数字方法的渐进提速,这种提速在矩阵维度上呈线性扩展。我们的算法利用了热力学原理,如遍历性、熵和平衡,突出了这两个看似不同的领域之间的深刻联系,并为热力学计算机开辟了代数应用领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Thermodynamic linear algebra

Thermodynamic linear algebra
Linear algebra is central to many algorithms in engineering, science, and machine learning; hence, accelerating it would have tremendous economic impact. Quantum computing has been proposed for this purpose, although the resource requirements are far beyond current technological capabilities. We consider an alternative physics-based computing paradigm based on classical thermodynamics, to provide a near-term approach to accelerating linear algebra. At first sight, thermodynamics and linear algebra seem to be unrelated fields. Here, we connect solving linear algebra problems to sampling from the thermodynamic equilibrium distribution of a system of coupled harmonic oscillators. We present simple thermodynamic algorithms for solving linear systems of equations, computing matrix inverses, and computing matrix determinants. Under reasonable assumptions, we rigorously establish asymptotic speedups for our algorithms, relative to digital methods, that scale linearly in matrix dimension. Our algorithms exploit thermodynamic principles like ergodicity, entropy, and equilibration, highlighting the deep connection between these two seemingly distinct fields, and opening up algebraic applications for thermodynamic computers.
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