TY - JOUR
T1 - A TWO-TIMESCALE STOCHASTIC ALGORITHM FRAMEWORK FOR BILEVEL OPTIMIZATION
T2 - COMPLEXITY ANALYSIS AND APPLICATION TO ACTOR-CRITIC
AU - Hong, Mingyi
AU - Wai, Hoi To
AU - Wang, Zhaoran
AU - Yang, Zhuoran
N1 - Publisher Copyright:
© 2023 Society for Industrial and Applied Mathematics.
PY - 2023
Y1 - 2023
N2 - This paper analyzes a two-timescale stochastic algorithm framework for bilevel optimization. Bilevel optimization is a class of problems which exhibits a two-level structure, and its goal is to minimize an outer objective function with variables which are constrained to be the optimal solution to an (inner) optimization problem. We consider the case when the inner problem is unconstrained and strongly convex, while the outer problem is constrained and has a smooth objective function. We propose a two-timescale stochastic approximation (TTSA) algorithm for tackling such a bilevel problem. In the algorithm, a stochastic gradient update with a larger step size is used for the inner problem, while a projected stochastic gradient update with a smaller step size is used for the outer problem. We analyze the convergence rates for the TTSA algorithm under various settings: when the outer problem is strongly convex (resp. weakly convex), the TTSA algorithm finds an O (Kmax-2/3)-optimal (resp. O (Kmax-2/5)-stationary) solution, where Kmax is the total iteration number. As an application, we show that a two-timescale natural actor-critic proximal policy optimization algorithm can be viewed as a special case of our TTSA framework. Importantly, the natural actor-critic algorithm is shown to converge at a rate of O (Kmax-1/4) in terms of the gap in expected discounted reward compared to a global optimal policy.
AB - This paper analyzes a two-timescale stochastic algorithm framework for bilevel optimization. Bilevel optimization is a class of problems which exhibits a two-level structure, and its goal is to minimize an outer objective function with variables which are constrained to be the optimal solution to an (inner) optimization problem. We consider the case when the inner problem is unconstrained and strongly convex, while the outer problem is constrained and has a smooth objective function. We propose a two-timescale stochastic approximation (TTSA) algorithm for tackling such a bilevel problem. In the algorithm, a stochastic gradient update with a larger step size is used for the inner problem, while a projected stochastic gradient update with a smaller step size is used for the outer problem. We analyze the convergence rates for the TTSA algorithm under various settings: when the outer problem is strongly convex (resp. weakly convex), the TTSA algorithm finds an O (Kmax-2/3)-optimal (resp. O (Kmax-2/5)-stationary) solution, where Kmax is the total iteration number. As an application, we show that a two-timescale natural actor-critic proximal policy optimization algorithm can be viewed as a special case of our TTSA framework. Importantly, the natural actor-critic algorithm is shown to converge at a rate of O (Kmax-1/4) in terms of the gap in expected discounted reward compared to a global optimal policy.
UR - http://www.scopus.com/inward/record.url?scp=85148719018&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85148719018&partnerID=8YFLogxK
U2 - 10.1137/20m1387341
DO - 10.1137/20m1387341
M3 - Article
AN - SCOPUS:85148719018
SN - 1052-6234
VL - 33
SP - 147
EP - 180
JO - SIAM Journal on Optimization
JF - SIAM Journal on Optimization
IS - 1
ER -