Bayesian Policy Optimization for Model Uncertainty
Bayesian Policy Optimization for Model Uncertainty
Addressing uncertainty is critical for autonomous systems to robustly adapt to the real world. We formulate the problem of model uncertainty as a continuous Bayes-Adaptive Markov Decision Process (BAMDP), where an agent maintains a posterior distribution over latent model parameters given a history of observations and maximizes its expected long-term reward with respect to this belief distribution. Our algorithm, Bayesian Policy Optimization, builds on recent policy optimization algorithms to learn a universal policy that navigates the exploration-exploitation trade-off to maximize the Bayesian value function. To address challenges from discretizing the continuous latent parameter space, we propose a new policy network architecture that encodes the belief distribution independently from the observable state. Our method significantly outperforms algorithms that address model uncertainty without explicitly reasoning about belief distributions and is competitive with state-of-the-art Partially Observable Markov Decision Process solvers.
Siddhartha S. Srinivasa、Jeongseok Lee、Gilwoo Lee、Aditya Mandalika、Sanjiban Choudhury、Brian Hou
自动化基础理论计算技术、计算机技术
Siddhartha S. Srinivasa,Jeongseok Lee,Gilwoo Lee,Aditya Mandalika,Sanjiban Choudhury,Brian Hou.Bayesian Policy Optimization for Model Uncertainty[EB/OL].(2018-10-01)[2025-06-10].https://arxiv.org/abs/1810.01014.点此复制
评论