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Autori principali: Dong, Yanjie, Zhang, Haijun, Wang, Gang, Cui, Shisheng, Hu, Xiping
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2408.06945
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author Dong, Yanjie
Zhang, Haijun
Wang, Gang
Cui, Shisheng
Hu, Xiping
author_facet Dong, Yanjie
Zhang, Haijun
Wang, Gang
Cui, Shisheng
Hu, Xiping
contents By using an parametric value function to replace the Monte-Carlo rollouts for value estimation, the actor-critic (AC) algorithms can reduce the variance of stochastic policy gradient so that to improve the convergence rate. While existing works mainly focus on analyzing convergence rate of AC algorithms under Markovian noise, the impacts of momentum on AC algorithms remain largely unexplored. In this work, we first propose a heavy-ball momentum based advantage actor-critic (\mbox{HB-A2C}) algorithm by integrating the heavy-ball momentum into the critic recursion that is parameterized by a linear function. When the sample trajectory follows a Markov decision process, we quantitatively certify the acceleration capability of the proposed HB-A2C algorithm. Our theoretical results demonstrate that the proposed HB-A2C finds an $ε$-approximate stationary point with $\oo{ε^{-2}}$ iterations for reinforcement learning tasks with Markovian noise. Moreover, we also reveal the dependence of learning rates on the length of the sample trajectory. By carefully selecting the momentum factor of the critic recursion, the proposed HB-A2C can balance the errors introduced by the initialization and the stoschastic approximation.
format Preprint
id arxiv_https___arxiv_org_abs_2408_06945
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Heavy-Ball Momentum Accelerated Actor-Critic With Function Approximation
Dong, Yanjie
Zhang, Haijun
Wang, Gang
Cui, Shisheng
Hu, Xiping
Machine Learning
Artificial Intelligence
By using an parametric value function to replace the Monte-Carlo rollouts for value estimation, the actor-critic (AC) algorithms can reduce the variance of stochastic policy gradient so that to improve the convergence rate. While existing works mainly focus on analyzing convergence rate of AC algorithms under Markovian noise, the impacts of momentum on AC algorithms remain largely unexplored. In this work, we first propose a heavy-ball momentum based advantage actor-critic (\mbox{HB-A2C}) algorithm by integrating the heavy-ball momentum into the critic recursion that is parameterized by a linear function. When the sample trajectory follows a Markov decision process, we quantitatively certify the acceleration capability of the proposed HB-A2C algorithm. Our theoretical results demonstrate that the proposed HB-A2C finds an $ε$-approximate stationary point with $\oo{ε^{-2}}$ iterations for reinforcement learning tasks with Markovian noise. Moreover, we also reveal the dependence of learning rates on the length of the sample trajectory. By carefully selecting the momentum factor of the critic recursion, the proposed HB-A2C can balance the errors introduced by the initialization and the stoschastic approximation.
title Heavy-Ball Momentum Accelerated Actor-Critic With Function Approximation
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2408.06945