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Hauptverfasser: Huang, Huaxing, Cui, Wenhao, Zhang, Tonghe, Li, Shengtao, Han, Jinchao, Qin, Bangyu, Zhang, Tianchu, Zheng, Liang, Tang, Ziyang, Hu, Chenxu, Yan, Ning, Chen, Jiahao, Zhang, Shipu, Jiang, Zheyuan
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2502.18901
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author Huang, Huaxing
Cui, Wenhao
Zhang, Tonghe
Li, Shengtao
Han, Jinchao
Qin, Bangyu
Zhang, Tianchu
Zheng, Liang
Tang, Ziyang
Hu, Chenxu
Yan, Ning
Chen, Jiahao
Zhang, Shipu
Jiang, Zheyuan
author_facet Huang, Huaxing
Cui, Wenhao
Zhang, Tonghe
Li, Shengtao
Han, Jinchao
Qin, Bangyu
Zhang, Tianchu
Zheng, Liang
Tang, Ziyang
Hu, Chenxu
Yan, Ning
Chen, Jiahao
Zhang, Shipu
Jiang, Zheyuan
contents While it is relatively easier to train humanoid robots to mimic specific locomotion skills, it is more challenging to learn from various motions and adhere to continuously changing commands. These robots must accurately track motion instructions, seamlessly transition between a variety of movements, and master intermediate motions not present in their reference data. In this work, we propose a novel approach that integrates human-like motion transfer with precise velocity tracking by a series of improvements to classical imitation learning. To enhance generalization, we employ the Wasserstein divergence criterion (WGAN-div). Furthermore, a Hybrid Internal Model provides structured estimates of hidden states and velocity to enhance mobile stability and environment adaptability, while a curiosity bonus fosters exploration. Our comprehensive method promises highly human-like locomotion that adapts to varying velocity requirements, direct generalization to unseen motions and multitasking, as well as zero-shot transfer to the simulator and the real world across different terrains. These advancements are validated through simulations across various robot models and extensive real-world experiments.
format Preprint
id arxiv_https___arxiv_org_abs_2502_18901
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Think on your feet: Seamless Transition between Human-like Locomotion in Response to Changing Commands
Huang, Huaxing
Cui, Wenhao
Zhang, Tonghe
Li, Shengtao
Han, Jinchao
Qin, Bangyu
Zhang, Tianchu
Zheng, Liang
Tang, Ziyang
Hu, Chenxu
Yan, Ning
Chen, Jiahao
Zhang, Shipu
Jiang, Zheyuan
Robotics
While it is relatively easier to train humanoid robots to mimic specific locomotion skills, it is more challenging to learn from various motions and adhere to continuously changing commands. These robots must accurately track motion instructions, seamlessly transition between a variety of movements, and master intermediate motions not present in their reference data. In this work, we propose a novel approach that integrates human-like motion transfer with precise velocity tracking by a series of improvements to classical imitation learning. To enhance generalization, we employ the Wasserstein divergence criterion (WGAN-div). Furthermore, a Hybrid Internal Model provides structured estimates of hidden states and velocity to enhance mobile stability and environment adaptability, while a curiosity bonus fosters exploration. Our comprehensive method promises highly human-like locomotion that adapts to varying velocity requirements, direct generalization to unseen motions and multitasking, as well as zero-shot transfer to the simulator and the real world across different terrains. These advancements are validated through simulations across various robot models and extensive real-world experiments.
title Think on your feet: Seamless Transition between Human-like Locomotion in Response to Changing Commands
topic Robotics
url https://arxiv.org/abs/2502.18901