English

Langevin dynamics based algorithm e-TH$\varepsilon$O POULA for stochastic optimization problems with discontinuous stochastic gradient

Optimization and Control 2024-07-02 v3 Machine Learning Numerical Analysis Numerical Analysis Probability Machine Learning

Abstract

We introduce a new Langevin dynamics based algorithm, called e-THε\varepsilonO POULA, to solve optimization problems with discontinuous stochastic gradients which naturally appear in real-world applications such as quantile estimation, vector quantization, CVaR minimization, and regularized optimization problems involving ReLU neural networks. We demonstrate both theoretically and numerically the applicability of the e-THε\varepsilonO POULA algorithm. More precisely, under the conditions that the stochastic gradient is locally Lipschitz in average and satisfies a certain convexity at infinity condition, we establish non-asymptotic error bounds for e-THε\varepsilonO POULA in Wasserstein distances and provide a non-asymptotic estimate for the expected excess risk, which can be controlled to be arbitrarily small. Three key applications in finance and insurance are provided, namely, multi-period portfolio optimization, transfer learning in multi-period portfolio optimization, and insurance claim prediction, which involve neural networks with (Leaky)-ReLU activation functions. Numerical experiments conducted using real-world datasets illustrate the superior empirical performance of e-THε\varepsilonO POULA compared to SGLD, TUSLA, ADAM, and AMSGrad in terms of model accuracy.

Keywords

Cite

@article{arxiv.2210.13193,
  title  = {Langevin dynamics based algorithm e-TH$\varepsilon$O POULA for stochastic optimization problems with discontinuous stochastic gradient},
  author = {Dong-Young Lim and Ariel Neufeld and Sotirios Sabanis and Ying Zhang},
  journal= {arXiv preprint arXiv:2210.13193},
  year   = {2024}
}
R2 v1 2026-06-28T04:21:14.709Z