Related papers: Offline Reinforcement Learning with Wasserstein Regularization via Optimal Transport Maps

Offline Reinforcement Learning with Wasserstein Regularization via Optimal Transport Maps

URL: http://arxiv.org/abs/2507.10843v1
Date: Mon, 14 Jul 2025 22:28:36 GMT
Title: Offline Reinforcement Learning with Wasserstein Regularization via Optimal Transport Maps
Authors: Motoki Omura, Yusuke Mukuta, Kazuki Ota, Takayuki Osa, Tatsuya Harada,
Abstract summary: offline reinforcement learning (RL) aims to learn an optimal policy from a static dataset.<n>We propose an approach that utilizes the Wasserstein distance, which is robust to out-of-distribution data.<n>Our approach demonstrates comparable or superior performance to widely used methods on the D4RL benchmark dataset.
Score: 47.57615889991631
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Offline reinforcement learning (RL) aims to learn an optimal policy from a static dataset, making it particularly valuable in scenarios where data collection is costly, such as robotics. A major challenge in offline RL is distributional shift, where the learned policy deviates from the dataset distribution, potentially leading to unreliable out-of-distribution actions. To mitigate this issue, regularization techniques have been employed. While many existing methods utilize density ratio-based measures, such as the $f$-divergence, for regularization, we propose an approach that utilizes the Wasserstein distance, which is robust to out-of-distribution data and captures the similarity between actions. Our method employs input-convex neural networks (ICNNs) to model optimal transport maps, enabling the computation of the Wasserstein distance in a discriminator-free manner, thereby avoiding adversarial training and ensuring stable learning. Our approach demonstrates comparable or superior performance to widely used existing methods on the D4RL benchmark dataset. The code is available at https://github.com/motokiomura/Q-DOT .

Related papers

Diverse Transformer Decoding for Offline Reinforcement Learning Using Financial Algorithmic Approaches [4.364595470673757]
Portfolio Beam Search (PBS) is a simple-yet-effective alternative to Beam Search (BS)<n>We develop an uncertainty-aware diversification mechanism, which we integrate into a sequential decoding algorithm at inference time.<n>We empirically demonstrate the effectiveness of PBS on the D4RL benchmark, where it achieves higher returns and significantly reduces outcome variability.
arXiv Detail & Related papers (2025-02-13T15:51:46Z)
CDSA: Conservative Denoising Score-based Algorithm for Offline Reinforcement Learning [25.071018803326254]
Distribution shift is a major obstacle in offline reinforcement learning. Previous conservative offline RL algorithms struggle to generalize to unseen actions. We propose to use the gradient fields of the dataset density generated from a pre-trained offline RL algorithm to adjust the original actions.
arXiv Detail & Related papers (2024-06-11T17:59:29Z)
Beyond Uniform Sampling: Offline Reinforcement Learning with Imbalanced Datasets [53.8218145723718]
offline policy learning is aimed at learning decision-making policies using existing datasets of trajectories without collecting additional data. We argue that when a dataset is dominated by suboptimal trajectories, state-of-the-art offline RL algorithms do not substantially improve over the average return of trajectories in the dataset. We present a realization of the sampling strategy and an algorithm that can be used as a plug-and-play module in standard offline RL algorithms.
arXiv Detail & Related papers (2023-10-06T17:58:14Z)
Let Offline RL Flow: Training Conservative Agents in the Latent Space of Normalizing Flows [58.762959061522736]
offline reinforcement learning aims to train a policy on a pre-recorded and fixed dataset without any additional environment interactions. We build upon recent works on learning policies in latent action spaces and use a special form of Normalizing Flows for constructing a generative model. We evaluate our method on various locomotion and navigation tasks, demonstrating that our approach outperforms recently proposed algorithms.
arXiv Detail & Related papers (2022-11-20T21:57:10Z)
Offline Reinforcement Learning with Adaptive Behavior Regularization [1.491109220586182]
offline reinforcement learning (RL) defines a sample-efficient learning paradigm, where a policy is learned from static and previously collected datasets. We propose a novel approach, which we refer to as adaptive behavior regularization (ABR) ABR enables the policy to adaptively adjust its optimization objective between cloning and improving over the policy used to generate the dataset.
arXiv Detail & Related papers (2022-11-15T15:59:11Z)
Boosting Offline Reinforcement Learning via Data Rebalancing [104.3767045977716]
offline reinforcement learning (RL) is challenged by the distributional shift between learning policies and datasets. We propose a simple yet effective method to boost offline RL algorithms based on the observation that resampling a dataset keeps the distribution support unchanged. We dub our method ReD (Return-based Data Rebalance), which can be implemented with less than 10 lines of code change and adds negligible running time.
arXiv Detail & Related papers (2022-10-17T16:34:01Z)
Latent-Variable Advantage-Weighted Policy Optimization for Offline RL [70.01851346635637]
offline reinforcement learning methods hold the promise of learning policies from pre-collected datasets without the need to query the environment for new transitions. In practice, offline datasets are often heterogeneous, i.e., collected in a variety of scenarios. We propose to leverage latent-variable policies that can represent a broader class of policy distributions. Our method improves the average performance of the next best-performing offline reinforcement learning methods by 49% on heterogeneous datasets.
arXiv Detail & Related papers (2022-03-16T21:17:03Z)
MOPO: Model-based Offline Policy Optimization [183.6449600580806]
offline reinforcement learning (RL) refers to the problem of learning policies entirely from a large batch of previously collected data. We show that an existing model-based RL algorithm already produces significant gains in the offline setting. We propose to modify the existing model-based RL methods by applying them with rewards artificially penalized by the uncertainty of the dynamics.
arXiv Detail & Related papers (2020-05-27T08:46:41Z)

This list is automatically generated from the titles and abstracts of the papers in this site.