Robust Asynchronous Stochastic Gradient-Push: Asymptotically Optimal and Network-Independent Performance for Strongly Convex Functions.

IF 4.3 3区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS Journal of Machine Learning Research Pub Date : 2020-01-01

Artin Spiridonoff, Alex Olshevsky, Ioannis Ch Paschalidis

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Abstract

We consider the standard model of distributed optimization of a sum of functions $F (z) = \sum_{i = 1}^{n} f_{i} (z)$ , where node i in a network holds the function f_i (z). We allow for a harsh network model characterized by asynchronous updates, message delays, unpredictable message losses, and directed communication among nodes. In this setting, we analyze a modification of the Gradient-Push method for distributed optimization, assuming that (i) node i is capable of generating gradients of its function f_i (z) corrupted by zero-mean bounded-support additive noise at each step, (ii) F(z) is strongly convex, and (iii) each f_i (z) has Lipschitz gradients. We show that our proposed method asymptotically performs as well as the best bounds on centralized gradient descent that takes steps in the direction of the sum of the noisy gradients of all the functions f ₁(z), …, f_n (z) at each step.

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鲁棒异步随机梯度推:强凸函数的渐近最优和网络无关性能。

我们考虑函数和的分布式优化的标准模型F (z) =∑i = 1 n F i (z)，其中网络中的节点i保存函数fi (z)。我们允许一个苛刻的网络模型，其特征是异步更新，消息延迟，不可预测的消息丢失和节点之间的定向通信。在此设置中，我们分析了用于分布式优化的Gradient-Push方法的修改，假设(i)节点i能够生成其函数fi (z)的梯度，该函数在每一步都被零均值有界支持加性噪声破坏，(ii) F(z)是强凸的，以及(iii)每个fi (z)具有Lipschitz梯度。我们表明，我们提出的方法在集中梯度下降上的渐近性能与最佳边界一样好，该方法在每一步都朝着所有函数f1 (z)，…，fn (z)的噪声梯度之和的方向采取步骤。

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来源期刊

Journal of Machine Learning Research 工程技术-计算机：人工智能

CiteScore

18.80

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： The Journal of Machine Learning Research (JMLR) provides an international forum for the electronic and paper publication of high-quality scholarly articles in all areas of machine learning. All published papers are freely available online. JMLR has a commitment to rigorous yet rapid reviewing. JMLR seeks previously unpublished papers on machine learning that contain: new principled algorithms with sound empirical validation, and with justification of theoretical, psychological, or biological nature; experimental and/or theoretical studies yielding new insight into the design and behavior of learning in intelligent systems; accounts of applications of existing techniques that shed light on the strengths and weaknesses of the methods; formalization of new learning tasks (e.g., in the context of new applications) and of methods for assessing performance on those tasks; development of new analytical frameworks that advance theoretical studies of practical learning methods; computational models of data from natural learning systems at the behavioral or neural level; or extremely well-written surveys of existing work.