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Symmetric Rank-One Quasi-Newton Methods for Deep Learning Using Cubic Regularization

Optimization and Control 2025-02-19 v1 Information Theory Machine Learning Numerical Analysis math.IT Numerical Analysis Machine Learning

Abstract

Stochastic gradient descent and other first-order variants, such as Adam and AdaGrad, are commonly used in the field of deep learning due to their computational efficiency and low-storage memory requirements. However, these methods do not exploit curvature information. Consequently, iterates can converge to saddle points or poor local minima. On the other hand, Quasi-Newton methods compute Hessian approximations which exploit this information with a comparable computational budget. Quasi-Newton methods re-use previously computed iterates and gradients to compute a low-rank structured update. The most widely used quasi-Newton update is the L-BFGS, which guarantees a positive semi-definite Hessian approximation, making it suitable in a line search setting. However, the loss functions in DNNs are non-convex, where the Hessian is potentially non-positive definite. In this paper, we propose using a limited-memory symmetric rank-one quasi-Newton approach which allows for indefinite Hessian approximations, enabling directions of negative curvature to be exploited. Furthermore, we use a modified adaptive regularized cubics approach, which generates a sequence of cubic subproblems that have closed-form solutions with suitable regularization choices. We investigate the performance of our proposed method on autoencoders and feed-forward neural network models and compare our approach to state-of-the-art first-order adaptive stochastic methods as well as other quasi-Newton methods.x

Keywords

Cite

@article{arxiv.2502.12298,
  title  = {Symmetric Rank-One Quasi-Newton Methods for Deep Learning Using Cubic Regularization},
  author = {Aditya Ranganath and Mukesh Singhal and Roummel Marcia},
  journal= {arXiv preprint arXiv:2502.12298},
  year   = {2025}
}

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R2 v1 2026-06-28T21:47:54.745Z