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Second-order Optimization for Non-convex Machine Learning: an Empirical Study

Peng Xu, Fred Roosta, Michael W. Mahoney

2020Society for Industrial and Applied Mathematics eBooks105 citationsDOIOpen Access PDF

Abstract

While first-order optimization methods, such as SGD are popular in machine learning (ML), they come with well-known deficiencies, including relatively-slow convergence, sensitivity to the settings of hyper-parameters such as learning rate, stagnation at high training errors, and difficulty in escaping flat regions and saddle points. These issues are particularly acute in highly non-convex settings such as those arising in neural networks. Motivated by this, there has been recent interest in second-order methods that aim to alleviate these shortcomings by capturing curvature information. In this paper, we report detailed empirical evaluations of a class of Newton-type methods, namely sub-sampled variants of trust region (TR) and adaptive regularization with cubics (ARC) algorithms, for non-convex ML problems. In doing so, we demonstrate that these methods not only can be computationally competitive with hand-tuned SGD with momentum, obtaining comparable or better generalization performance, but also they are highly robust to hyper-parameter settings. Further, we show that the manner in which these Newton-type methods employ curvature information allows them to seamlessly escape flat regions and saddle points.

Topics & Concepts

Saddle pointCurvatureRegular polygonRegularization (linguistics)Artificial intelligenceComputer scienceConvex functionDeep neural networksRate of convergenceSensitivity (control systems)Mathematical optimizationMachine learningAlgorithmArtificial neural networkMathematicsKey (lock)GeometryEngineeringComputer securityElectronic engineeringStochastic Gradient Optimization TechniquesSparse and Compressive Sensing TechniquesAdvanced Optimization Algorithms Research