English

Accelerating Optimization and Reinforcement Learning with Quasi-Stochastic Approximation

Optimization and Control 2020-10-02 v2 Machine Learning

Abstract

The ODE method has been a workhorse for algorithm design and analysis since the introduction of the stochastic approximation. It is now understood that convergence theory amounts to establishing robustness of Euler approximations for ODEs, while theory of rates of convergence requires finer analysis. This paper sets out to extend this theory to quasi-stochastic approximation, based on algorithms in which the "noise" is based on deterministic signals. The main results are obtained under minimal assumptions: the usual Lipschitz conditions for ODE vector fields, and it is assumed that there is a well defined linearization near the optimal parameter θ\theta^*, with Hurwitz linearization matrix AA^*. The main contributions are summarized as follows: (i) If the algorithm gain is at=g/(1+t)ρa_t=g/(1+t)^\rho with g>0g>0 and ρ(0,1)\rho\in(0,1), then the rate of convergence of the algorithm is 1/tρ1/t^\rho. There is also a well defined "finite-tt" approximation: at1{Θtθ}=Yˉ+ΞtI+o(1) a_t^{-1}\{\Theta_t-\theta^*\}=\bar{Y}+\Xi^{\mathrm{I}}_t+o(1) where YˉRd\bar{Y}\in\mathbb{R}^d is a vector identified in the paper, and {ΞtI}\{\Xi^{\mathrm{I}}_t\} is bounded with zero temporal mean. (ii) With gain at=g/(1+t)a_t = g/(1+t) the results are not as sharp: the rate of convergence 1/t1/t holds only if I+gAI + g A^* is Hurwitz. (iii) Based on the Ruppert-Polyak averaging of stochastic approximation, one would expect that a convergence rate of 1/t1/t can be obtained by averaging: ΘTRP=1T0TΘtdt \Theta^{\text{RP}}_T=\frac{1}{T}\int_{0}^T \Theta_t\,dt where the estimates {Θt}\{\Theta_t\} are obtained using the gain in (i). The preceding sharp bounds imply that averaging results in 1/t1/t convergence rate if and only if Yˉ=0\bar{Y}=\sf 0. This condition holds if the noise is additive, but appears to fail in general. (iv) The theory is illustrated with applications to gradient-free optimization and policy gradient algorithms for reinforcement learning.

Keywords

Cite

@article{arxiv.2009.14431,
  title  = {Accelerating Optimization and Reinforcement Learning with Quasi-Stochastic Approximation},
  author = {Shuhang Chen and Adithya Devraj and Andrey Bernstein and Sean Meyn},
  journal= {arXiv preprint arXiv:2009.14431},
  year   = {2020}
}
R2 v1 2026-06-23T18:53:58.469Z