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Autori principali: Zhou, Shengli, Wang, Xiangchen, Zhang, Jinrui, Tian, Ruozai, Xu, Rongtao, Zheng, Feng
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.07033
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author Zhou, Shengli
Wang, Xiangchen
Zhang, Jinrui
Tian, Ruozai
Xu, Rongtao
Zheng, Feng
author_facet Zhou, Shengli
Wang, Xiangchen
Zhang, Jinrui
Tian, Ruozai
Xu, Rongtao
Zheng, Feng
contents Embodied agents have shown promising generalization capabilities across diverse physical environments, making them essential for a wide range of real-world applications. However, building versatile embodied agents poses critical challenges due to three key issues: dynamic environment perception, open-ended tool usage, and complex multi-task planning. Most previous works rely solely on feedback from tool agents to perceive environmental changes and task status, which limits adaptability to real-time dynamics, causes error accumulation, and restricts tool flexibility. Furthermore, multi-task scheduling has received limited attention, primarily due to the inherent complexity of managing task dependencies and balancing competing priorities in dynamic and complex environments. To overcome these challenges, we introduce $\mathcal{P}^3$, a unified framework that integrates real-time perception and dynamic scheduling. Specifically, $\mathcal{P}^3$ enables 1) \textbf Perceive relevant task information actively from the environment, 2) \textbf Plug and utilize any tool without feedback requirement, and 3) \textbf Plan multi-task execution based on prioritizing urgent tasks and dynamically adjusting task order based on dependencies. Extensive real-world experiments show that our approach bridges the gap between benchmarks and practical deployment, delivering highly transferable, general-purpose embodied agents. Code and data will be released soon.
format Preprint
id arxiv_https___arxiv_org_abs_2508_07033
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle $\mathcal{P}^3$: Toward Versatile Embodied Agents
Zhou, Shengli
Wang, Xiangchen
Zhang, Jinrui
Tian, Ruozai
Xu, Rongtao
Zheng, Feng
Robotics
Embodied agents have shown promising generalization capabilities across diverse physical environments, making them essential for a wide range of real-world applications. However, building versatile embodied agents poses critical challenges due to three key issues: dynamic environment perception, open-ended tool usage, and complex multi-task planning. Most previous works rely solely on feedback from tool agents to perceive environmental changes and task status, which limits adaptability to real-time dynamics, causes error accumulation, and restricts tool flexibility. Furthermore, multi-task scheduling has received limited attention, primarily due to the inherent complexity of managing task dependencies and balancing competing priorities in dynamic and complex environments. To overcome these challenges, we introduce $\mathcal{P}^3$, a unified framework that integrates real-time perception and dynamic scheduling. Specifically, $\mathcal{P}^3$ enables 1) \textbf Perceive relevant task information actively from the environment, 2) \textbf Plug and utilize any tool without feedback requirement, and 3) \textbf Plan multi-task execution based on prioritizing urgent tasks and dynamically adjusting task order based on dependencies. Extensive real-world experiments show that our approach bridges the gap between benchmarks and practical deployment, delivering highly transferable, general-purpose embodied agents. Code and data will be released soon.
title $\mathcal{P}^3$: Toward Versatile Embodied Agents
topic Robotics
url https://arxiv.org/abs/2508.07033