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Auteurs principaux: Gorodetskiy, Andrey, Mironov, Konstantin, Panov, Aleksandr
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2407.13518
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author Gorodetskiy, Andrey
Mironov, Konstantin
Panov, Aleksandr
author_facet Gorodetskiy, Andrey
Mironov, Konstantin
Panov, Aleksandr
contents The application of learning-based control methods in robotics presents significant challenges. One is that model-free reinforcement learning algorithms use observation data with low sample efficiency. To address this challenge, a prevalent approach is model-based reinforcement learning, which involves employing an environment dynamics model. We suggest approximating transition dynamics with symbolic expressions, which are generated via symbolic regression. Approximation of a mechanical system with a symbolic model has fewer parameters than approximation with neural networks, which can potentially lead to higher accuracy and quality of extrapolation. We use a symbolic dynamics model to generate trajectories in model-based policy optimization to improve the sample efficiency of the learning algorithm. We evaluate our approach across various tasks within simulated environments. Our method demonstrates superior sample efficiency in these tasks compared to model-free and model-based baseline methods.
format Preprint
id arxiv_https___arxiv_org_abs_2407_13518
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Model-based Policy Optimization using Symbolic World Model
Gorodetskiy, Andrey
Mironov, Konstantin
Panov, Aleksandr
Machine Learning
The application of learning-based control methods in robotics presents significant challenges. One is that model-free reinforcement learning algorithms use observation data with low sample efficiency. To address this challenge, a prevalent approach is model-based reinforcement learning, which involves employing an environment dynamics model. We suggest approximating transition dynamics with symbolic expressions, which are generated via symbolic regression. Approximation of a mechanical system with a symbolic model has fewer parameters than approximation with neural networks, which can potentially lead to higher accuracy and quality of extrapolation. We use a symbolic dynamics model to generate trajectories in model-based policy optimization to improve the sample efficiency of the learning algorithm. We evaluate our approach across various tasks within simulated environments. Our method demonstrates superior sample efficiency in these tasks compared to model-free and model-based baseline methods.
title Model-based Policy Optimization using Symbolic World Model
topic Machine Learning
url https://arxiv.org/abs/2407.13518