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Main Authors: van der Vaart, Pascal R., Yorke-Smith, Neil, Spaan, Matthijs T. J.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.21488
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author van der Vaart, Pascal R.
Yorke-Smith, Neil
Spaan, Matthijs T. J.
author_facet van der Vaart, Pascal R.
Yorke-Smith, Neil
Spaan, Matthijs T. J.
contents Uncertainty quantification in reinforcement learning can greatly improve exploration and robustness. Approximate Bayesian approaches have recently been popularized to quantify uncertainty in model-free algorithms. However, so far the focus has been on improving the accuracy of the posterior approximation, instead of studying the accuracy of the prior and likelihood assumptions underlying the posterior. In this work, we demonstrate that there is a cold posterior effect in Bayesian deep Q-learning, where contrary to theory, performance increases when reducing the temperature of the posterior. To identify and overcome likely causes, we challenge common assumptions made on the likelihood and priors in Bayesian model-free algorithms. We empirically study prior distributions and show through statistical tests that the common Gaussian likelihood assumption is frequently violated. We argue that developing more suitable likelihoods and priors should be a key focus in future Bayesian reinforcement learning research and we offer simple, implementable solutions for better priors in deep Q-learning that lead to more performant Bayesian algorithms.
format Preprint
id arxiv_https___arxiv_org_abs_2508_21488
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Priors Matter: Addressing Misspecification in Bayesian Deep Q-Learning
van der Vaart, Pascal R.
Yorke-Smith, Neil
Spaan, Matthijs T. J.
Machine Learning
Artificial Intelligence
Uncertainty quantification in reinforcement learning can greatly improve exploration and robustness. Approximate Bayesian approaches have recently been popularized to quantify uncertainty in model-free algorithms. However, so far the focus has been on improving the accuracy of the posterior approximation, instead of studying the accuracy of the prior and likelihood assumptions underlying the posterior. In this work, we demonstrate that there is a cold posterior effect in Bayesian deep Q-learning, where contrary to theory, performance increases when reducing the temperature of the posterior. To identify and overcome likely causes, we challenge common assumptions made on the likelihood and priors in Bayesian model-free algorithms. We empirically study prior distributions and show through statistical tests that the common Gaussian likelihood assumption is frequently violated. We argue that developing more suitable likelihoods and priors should be a key focus in future Bayesian reinforcement learning research and we offer simple, implementable solutions for better priors in deep Q-learning that lead to more performant Bayesian algorithms.
title Priors Matter: Addressing Misspecification in Bayesian Deep Q-Learning
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2508.21488