Double Gumbel Q-Learning

David Yu-Tung Hui; Aaron C. Courville; Pierre-Luc Bacon

2023 NIPS NeurIPS 2023

Double Gumbel Q-Learning

Abstract

We show that Deep Neural Networks introduce two heteroscedastic Gumbel noise sources into Q-Learning. To account for these noise sources, we propose Double Gumbel Q-Learning, a Deep Q-Learning algorithm applicable for both discrete and continuous control. In discrete control, we derive a closed-form expression for the loss function of our algorithm. In continuous control, this loss function is intractable and we therefore derive an approximation with a hyperparameter whose value regulates pessimism in Q-Learning. We present a default value for our pessimism hyperparameter that enables DoubleGum to outperform DDPG, TD3, SAC, XQL, quantile regression, and Mixture-of-Gaussian Critics in aggregate over 33 tasks from DeepMind Control, MuJoCo, MetaWorld, and Box2D and show that tuning this hyperparameter may further improve sample efficiency.

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics

Authors

David Yu-Tung Hui , Aaron C. Courville , Pierre-Luc Bacon

Topics

Artificial Intelligence > Core AI > Agent Systems

Keywords

continuous control deep q-learning pessimistic exploration discrete control gumbel noise

Download PDF

Related papers

Risk-Averse Model Uncertainty for Distributionally Robust Safe Reinforcement Learning 2023

Generative Modeling through the Semi-dual Formulation of Unbalanced Optimal Transport 2023

Self-Supervised Motion Magnification by Backpropagating Through Optical Flow 2023

Diffused Task-Agnostic Milestone Planner 2023

Characterizing Graph Datasets for Node Classification: Homophily-Heterophily Dichotomy and Beyond 2023