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Practical Probabilistic Model-Based Reinforcement Learning by Integrating Dropout Uncertainty and Trajectory Sampling

Wenjun Huang, Yunduan Cui, Huiyun Li, Xinyu Wu

2024IEEE Transactions on Neural Networks and Learning Systems11 citationsDOI

Abstract

This article addresses the prediction stability, prediction accuracy, and control capability of the current probabilistic model-based reinforcement learning (MBRL) built on neural networks. A novel approach to dropout-based probabilistic ensembles with trajectory sampling (DPETS) is proposed, where the system uncertainty is stably predicted by combining the Monte Carlo dropout (MC Dropout) and trajectory sampling in one framework. Its loss function is designed to correct the fitting error of neural networks for more accurate prediction of probabilistic models. The state propagation in its policy is extended to filter the aleatoric uncertainty for superior control capability. Evaluated by several Mujoco benchmark control tasks under additional disturbances and one practical robot arm manipulation task, DPETS outperforms related MBRL approaches in both average return and convergence velocity while achieving superior performance than well-known model-free baselines with significant sample efficiency. The open-source code of DPETS is available at https://github.com/mrjun123/DPETS.

Topics & Concepts

Dropout (neural networks)Probabilistic logicTrajectoryReinforcement learningComputer scienceSampling (signal processing)Artificial intelligenceMachine learningImportance samplingStatisticsMonte Carlo methodMathematicsComputer visionAstronomyPhysicsFilter (signal processing)Autonomous Vehicle Technology and SafetyTraffic control and managementHuman-Automation Interaction and Safety
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