English

Derivative-Free Methods for Policy Optimization: Guarantees for Linear Quadratic Systems

Machine Learning 2020-05-19 v3 Optimization and Control Machine Learning

Abstract

We study derivative-free methods for policy optimization over the class of linear policies. We focus on characterizing the convergence rate of these methods when applied to linear-quadratic systems, and study various settings of driving noise and reward feedback. We show that these methods provably converge to within any pre-specified tolerance of the optimal policy with a number of zero-order evaluations that is an explicit polynomial of the error tolerance, dimension, and curvature properties of the problem. Our analysis reveals some interesting differences between the settings of additive driving noise and random initialization, as well as the settings of one-point and two-point reward feedback. Our theory is corroborated by extensive simulations of derivative-free methods on these systems. Along the way, we derive convergence rates for stochastic zero-order optimization algorithms when applied to a certain class of non-convex problems.

Keywords

Cite

@article{arxiv.1812.08305,
  title  = {Derivative-Free Methods for Policy Optimization: Guarantees for Linear Quadratic Systems},
  author = {Dhruv Malik and Ashwin Pananjady and Kush Bhatia and Koulik Khamaru and Peter L. Bartlett and Martin J. Wainwright},
  journal= {arXiv preprint arXiv:1812.08305},
  year   = {2020}
}

Comments

Version v3 consistent with paper appearing in JMLR

R2 v1 2026-06-23T06:50:29.864Z