English

Uncertainty Quantification for Gradient and Accelerated Gradient Descent Methods on Strongly Convex Functions

Optimization and Control 2021-12-02 v2

Abstract

We consider the problem of minimizing a strongly convex function that depends on an uncertain parameter θ\theta. The uncertainty in the objective function means that the optimum, x(θ)x^*(\theta), is also a function of θ\theta. We propose an efficient method to compute x(θ)x^*(\theta) and its statistics. We use a chaos expansion of x(θ)x^*(\theta) along a truncated basis and study first-order methods that compute the optimal coefficients. We establish the convergence rate of the method as the number of basis functions, and hence the dimensionality of the optimization problem is increased. We give the first non-asymptotic rates for the gradient descent and the accelerated gradient descent methods. Our analysis exploits convexity and does not rely on a diminishing step-size strategy. As a result, it is much faster than the state-of-the-art both in theory and in our preliminary numerical experiments. A surprising side-effect of our analysis is that the proposed method also acts as a variance reduction technique to the problem of estimating x(θ)x^*(\theta).

Keywords

Cite

@article{arxiv.2111.02836,
  title  = {Uncertainty Quantification for Gradient and Accelerated Gradient Descent Methods on Strongly Convex Functions},
  author = {Conor McMeel and Panos Parpas},
  journal= {arXiv preprint arXiv:2111.02836},
  year   = {2021}
}

Comments

Minor presentation edits only. Submitted to SIAM UQ Journal

R2 v1 2026-06-24T07:26:03.688Z