应用于零阶联合学习的增量赫赛斯估计新界限

Alessio Maritan;Luca Schenato;Subhrakanti Dey
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引用次数: 0

摘要

黑森矩阵传达了函数的曲率、频谱和偏导数等重要信息,在各种任务中都需要使用。然而,计算精确的黑森矩阵对于高维输入空间来说过于昂贵,而且在零阶优化中也是不可能的,因为在零阶优化中,目标函数是一个黑箱,只有输入输出对是已知的。在这项工作中,我们通过对文献中的一个黑森估计器进行严格分析,解决了这一相关问题,使其可以用作真正黑森矩阵的可证明精确替代物。黑森估计器是随机和增量的,其计算只需要点函数求值。我们提供了估计误差的非渐近收敛边界,并推导出了以任意高的概率达到预期精度所需的最小函数查询次数。在论文的第二部分,我们展示了我们成果的实际应用,介绍了一种适用于非凸和黑箱联合学习的新型优化算法。该算法只要求客户在特定输入点评估其局部函数,并以分布式方式建立足够精确的全局赫塞斯矩阵估计值。该算法利用非精确立方正则化来摆脱鞍点,并保证以最佳迭代复杂度和高概率收敛。数值结果表明,在凸问题和非凸问题上,所提出的算法都优于现有的零阶联合算法。此外,我们还取得了与使用精确梯度和黑森矩阵的最先进联合凸优化算法类似的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Novel Bounds for Incremental Hessian Estimation With Application to Zeroth-Order Federated Learning
The Hessian matrix conveys important information about the curvature, spectrum and partial derivatives of a function, and is required in a variety of tasks. However, computing the exact Hessian is prohibitively expensive for high-dimensional input spaces, and is just impossible in zeroth-order optimization, where the objective function is a black-box of which only input-output pairs are known. In this work we address this relevant problem by providing a rigorous analysis of an Hessian estimator available in the literature, allowing it to be used as a provably accurate replacement of the true Hessian matrix. The Hessian estimator is randomized and incremental, and its computation requires only point function evaluations. We provide non-asymptotic convergence bounds on the estimation error and derive the minimum number of function queries needed to achieve a desired accuracy with arbitrarily high probability. In the second part of the paper we show a practical application of our results, introducing a novel optimization algorithm suitable for non-convex and black-box federated learning. The algorithm only requires clients to evaluate their local functions at certain input points, and builds a sufficiently accurate estimate of the global Hessian matrix in a distributed way. The algorithm exploits inexact cubic regularization to escape saddle points and guarantees convergence with optimal iteration complexity and high probability. Numerical results show that the proposed algorithm outperforms the existing zeroth-order federated algorithms in both convex and non-convex problems. Furthermore, we achieve similar performance to state-of-the-art algorithms for federated convex optimization that use exact gradients and Hessian matrices.
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