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Context-Based Meta-Reinforcement Learning With Bayesian Nonparametric Models

Zhenshan Bing, Yuqi Yun, Kai Huang, Alois Knoll

2024IEEE Transactions on Pattern Analysis and Machine Intelligence11 citationsDOIOpen Access PDF

Abstract

Deep reinforcement learning agents usually need to collect a large number of interactions to solve a single task. In contrast, meta-reinforcement learning (meta-RL) aims to quickly adapt to new tasks using a small amount of experience by leveraging the knowledge from training on a set of similar tasks. State-of-the-art context-based meta-RL algorithms use the context to encode the task information and train a policy conditioned on the inferred latent task encoding. However, most recent works are limited to parametric tasks, where a handful of variables control the full variation in the task distribution, and also failed to work in non-stationary environments due to the few-shot adaptation setting. To address those limitations, we propose MEta-reinforcement Learning with Task Self-discovery (MELTS), which adaptively learns qualitatively different nonparametric tasks and adapts to new tasks in a zero-shot manner. We introduce a novel deep clustering framework (DPMM-VAE) based on an infinite mixture of Gaussians, which combines the Dirichlet process mixture model (DPMM) and the variational autoencoder (VAE), to simultaneously learn task representations and cluster the tasks in a self-adaptive way. Integrating DPMM-VAE into MELTS enables it to adaptively discover the multi-modal structure of the nonparametric task distribution, which previous methods using isotropic Gaussian random variables cannot model. In addition, we propose a zero-shot adaptation mechanism and a recurrence-based context encoding strategy to improve the data efficiency and make our algorithm applicable in non-stationary environments. On various continuous control tasks with both parametric and nonparametric variations, our algorithm produces a more structured and self-adaptive task latent space and also achieves superior sample efficiency and asymptotic performance compared with state-of-the-art meta-RL algorithms.

Topics & Concepts

Artificial intelligenceComputer scienceReinforcement learningMachine learningBayesian probabilityContext (archaeology)Nonparametric statisticsPattern recognition (psychology)MathematicsEconometricsPaleontologyBiologyBayesian Methods and Mixture ModelsGaussian Processes and Bayesian InferenceAdvanced Multi-Objective Optimization Algorithms
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