Hardness of Random Optimization Problems for Boolean Circuits, Low-Degree Polynomials, and Langevin Dynamics

IF 1.2 3区 计算机科学 Q3 COMPUTER SCIENCE, THEORY & METHODS
David Gamarnik, Aukosh Jagannath, Alexander S. Wein
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引用次数: 0

Abstract

SIAM Journal on Computing, Volume 53, Issue 1, Page 1-46, February 2024.
Abstract. We consider the problem of finding nearly optimal solutions of optimization problems with random objective functions. Such problems arise widely in the theory of random graphs, theoretical computer science, and statistical physics. Two concrete problems we consider are (a) optimizing the Hamiltonian of a spherical or Ising [math]-spin glass model and (b) finding a large independent set in a sparse Erdős–Rényi graph. The following families of algorithms are considered: (a) low-degree polynomials of the input—a general framework that captures many prior algorithms; (b) low-depth Boolean circuits; (c) the Langevin dynamics algorithm, a canonical Monte Carlo analogue of the gradient descent algorithm. We show that these families of algorithms cannot have high success probability. For the case of Boolean circuits, our results improve the state-of-the-art bounds known in circuit complexity theory (although we consider the search problem as opposed to the decision problem). Our proof uses the fact that these models are known to exhibit a variant of the overlap gap property (OGP) of near-optimal solutions. Specifically, for both models, every two solutions whose objectives are above a certain threshold are either close to or far from each other. The crux of our proof is that the classes of algorithms we consider exhibit a form of stability (noise-insensitivity): a small perturbation of the input induces a small perturbation of the output. We show by an interpolation argument that stable algorithms cannot overcome the OGP barrier. The stability of Langevin dynamics is an immediate consequence of the well-posedness of stochastic differential equations. The stability of low-degree polynomials and Boolean circuits is established using tools from Gaussian and Boolean analysis—namely hypercontractivity and total influence, as well as a novel lower bound for random walks avoiding certain subsets, which we expect to be of independent interest. In the case of Boolean circuits, the result also makes use of Linial–Mansour–Nisan’s classical theorem. Our techniques apply more broadly to low influence functions, and we expect that they may apply more generally.
布尔电路、低度多项式和朗文动力学随机优化问题的难易程度
SIAM 计算期刊》第 53 卷第 1 期第 1-46 页,2024 年 2 月。 摘要我们考虑的问题是为具有随机目标函数的优化问题寻找近似最优解。这类问题广泛出现在随机图理论、理论计算机科学和统计物理学中。我们考虑的两个具体问题是:(a) 优化球面或伊辛[math]-自旋玻璃模型的哈密顿;(b) 在稀疏厄尔多斯-雷尼图中寻找大的独立集。我们考虑了以下几种算法:(a) 输入的低度多项式--一种涵盖了许多先前算法的通用框架;(b) 低深度布尔电路;(c) Langevin 动态算法--梯度下降算法的典型蒙特卡洛类似算法。我们证明,这些算法系列不可能有很高的成功概率。就布尔电路而言,我们的结果改进了电路复杂性理论中已知的最新界限(尽管我们考虑的是搜索问题而不是决策问题)。我们的证明利用了这样一个事实,即已知这些模型表现出近乎最优解的重叠间隙特性(OGP)的变体。具体来说,对于这两种模型,每两个目标高于某个阈值的解要么相互接近,要么相互远离。我们证明的关键在于,我们考虑的这几类算法都表现出一种稳定性(对噪声不敏感):输入的微小扰动会引起输出的微小扰动。我们通过插值论证证明,稳定算法无法克服 OGP 障碍。朗格文动力学的稳定性是随机微分方程良好拟合的直接结果。低度多项式和布尔电路的稳定性是利用高斯分析和布尔分析的工具--即超收缩性和总影响,以及避开某些子集的随机漫步的新下限建立的,我们希望这些工具能引起独立的兴趣。在布尔电路的情况下,该结果还利用了 Linial-Mansour-Nisan 的经典定理。我们的技术更广泛地适用于低影响函数,我们希望它们能更普遍地应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
SIAM Journal on Computing
SIAM Journal on Computing 工程技术-计算机:理论方法
CiteScore
4.60
自引率
0.00%
发文量
68
审稿时长
6-12 weeks
期刊介绍: The SIAM Journal on Computing aims to provide coverage of the most significant work going on in the mathematical and formal aspects of computer science and nonnumerical computing. Submissions must be clearly written and make a significant technical contribution. Topics include but are not limited to analysis and design of algorithms, algorithmic game theory, data structures, computational complexity, computational algebra, computational aspects of combinatorics and graph theory, computational biology, computational geometry, computational robotics, the mathematical aspects of programming languages, artificial intelligence, computational learning, databases, information retrieval, cryptography, networks, distributed computing, parallel algorithms, and computer architecture.
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