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Learning Interpretable, High-Performing Policies for Autonomous Driving

Rohan Paleja, Yaru Niu, Andrew Silva, Chace Ritchie, Sugju Choi, Matthew Gombolay

202213 citationsDOIOpen Access PDF

Abstract

Gradient-based approaches in reinforcement learning (RL) have achieved tremendous success in learning policies for autonomous vehicles. While the performance of these approaches warrants real-world adoption, these policies lack interpretability, limiting deployability in the safety-critical and legally-regulated domain of autonomous driving (AD). AD requires interpretable and verifiable control policies that maintain high performance. We propose Interpretable Continuous Control Trees (ICCTs), a tree-based model that can be optimized via modern, gradient-based, RL approaches to produce highperforming, interpretable policies. The key to our approach is a procedure for allowing direct optimization in a sparse decisiontree-like representation. We validate ICCTs against baselines across six domains, showing that ICCTs are capable of learning interpretable policy representations that parity or outperform baselines by up to 33% in AD scenarios while achieving a 300x-600x reduction in the number of policy parameters against deep learning baselines. Furthermore, we demonstrate the interpretability and utility of our ICCTs through a 14-car physical robot demonstration. i x k -b i > 0). As each leaf node is represented as a probability mass function over output classes in prior work, leaf nodes, l, must be modified to produce

Topics & Concepts

Computer scienceArtificial intelligenceTopic ModelingExplainable Artificial Intelligence (XAI)Machine Learning and Data Classification
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