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Main Authors: Ye, Lei, Gao, Haibo, Xu, Peng, Zhang, Zhelin, Shan, Junqi, Zhang, Ao, Zhang, Wei, Zhou, Ruyi, Deng, Zongquan, Ding, Liang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.08435
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author Ye, Lei
Gao, Haibo
Xu, Peng
Zhang, Zhelin
Shan, Junqi
Zhang, Ao
Zhang, Wei
Zhou, Ruyi
Deng, Zongquan
Ding, Liang
author_facet Ye, Lei
Gao, Haibo
Xu, Peng
Zhang, Zhelin
Shan, Junqi
Zhang, Ao
Zhang, Wei
Zhou, Ruyi
Deng, Zongquan
Ding, Liang
contents Diffusion models offer powerful generative capabilities for robot trajectory planning, yet their practical deployment on robots is hindered by a critical bottleneck: a reliance on imitation learning from expert demonstrations. This paradigm is often impractical for specialized robots where data is scarce and creates an inefficient, theoretically suboptimal training pipeline. To overcome this, we introduce PegasusFlow, a hierarchical rolling-denoising framework that enables direct and parallel sampling of trajectory score gradients from environmental interaction, completely bypassing the need for expert data. Our core innovation is a novel sampling algorithm, Weighted Basis Function Optimization (WBFO), which leverages spline basis representations to achieve superior sample efficiency and faster convergence compared to traditional methods like MPPI. The framework is embedded within a scalable, asynchronous parallel simulation architecture that supports massively parallel rollouts for efficient data collection. Extensive experiments on trajectory optimization and robotic navigation tasks demonstrate that our approach, particularly Action-Value WBFO (AVWBFO) combined with a reinforcement learning warm-start, significantly outperforms baselines. In a challenging barrier-crossing task, our method achieved a 100% success rate and was 18% faster than the next-best method, validating its effectiveness for complex terrain locomotion planning. https://masteryip.github.io/pegasusflow.github.io/
format Preprint
id arxiv_https___arxiv_org_abs_2509_08435
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle PegasusFlow: Parallel Rolling-Denoising Score Sampling for Robot Diffusion Planner Flow Matching
Ye, Lei
Gao, Haibo
Xu, Peng
Zhang, Zhelin
Shan, Junqi
Zhang, Ao
Zhang, Wei
Zhou, Ruyi
Deng, Zongquan
Ding, Liang
Robotics
Diffusion models offer powerful generative capabilities for robot trajectory planning, yet their practical deployment on robots is hindered by a critical bottleneck: a reliance on imitation learning from expert demonstrations. This paradigm is often impractical for specialized robots where data is scarce and creates an inefficient, theoretically suboptimal training pipeline. To overcome this, we introduce PegasusFlow, a hierarchical rolling-denoising framework that enables direct and parallel sampling of trajectory score gradients from environmental interaction, completely bypassing the need for expert data. Our core innovation is a novel sampling algorithm, Weighted Basis Function Optimization (WBFO), which leverages spline basis representations to achieve superior sample efficiency and faster convergence compared to traditional methods like MPPI. The framework is embedded within a scalable, asynchronous parallel simulation architecture that supports massively parallel rollouts for efficient data collection. Extensive experiments on trajectory optimization and robotic navigation tasks demonstrate that our approach, particularly Action-Value WBFO (AVWBFO) combined with a reinforcement learning warm-start, significantly outperforms baselines. In a challenging barrier-crossing task, our method achieved a 100% success rate and was 18% faster than the next-best method, validating its effectiveness for complex terrain locomotion planning. https://masteryip.github.io/pegasusflow.github.io/
title PegasusFlow: Parallel Rolling-Denoising Score Sampling for Robot Diffusion Planner Flow Matching
topic Robotics
url https://arxiv.org/abs/2509.08435