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Representation Learning in Deep RL via Discrete Information Bottleneck

Machine Learning 2023-06-01 v2

Abstract

Several self-supervised representation learning methods have been proposed for reinforcement learning (RL) with rich observations. For real-world applications of RL, recovering underlying latent states is crucial, particularly when sensory inputs contain irrelevant and exogenous information. In this work, we study how information bottlenecks can be used to construct latent states efficiently in the presence of task-irrelevant information. We propose architectures that utilize variational and discrete information bottlenecks, coined as RepDIB, to learn structured factorized representations. Exploiting the expressiveness bought by factorized representations, we introduce a simple, yet effective, bottleneck that can be integrated with any existing self-supervised objective for RL. We demonstrate this across several online and offline RL benchmarks, along with a real robot arm task, where we find that compressed representations with RepDIB can lead to strong performance improvements, as the learned bottlenecks help predict only the relevant state while ignoring irrelevant information.

Keywords

Cite

@article{arxiv.2212.13835,
  title  = {Representation Learning in Deep RL via Discrete Information Bottleneck},
  author = {Riashat Islam and Hongyu Zang and Manan Tomar and Aniket Didolkar and Md Mofijul Islam and Samin Yeasar Arnob and Tariq Iqbal and Xin Li and Anirudh Goyal and Nicolas Heess and Alex Lamb},
  journal= {arXiv preprint arXiv:2212.13835},
  year   = {2023}
}

Comments

AISTATS 2023

R2 v1 2026-06-28T07:54:49.847Z