HAC-LOCO: Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances

Xiang Zhou; Xinyu Zhang; Tong Wu; Qingrui Zhang; Lixian Zhang

doi:10.1109/IROS60139.2025.11247775

HAC-LOCO: Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances

Xiang Zhou
, Xinyu Zhang
, Tong Wu
, Qingrui Zhang^*
, Lixian Zhang^*

^*Corresponding author for this work

School of Astronautics

Sun Yat-Sen University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Despite recent remarkable achievements in quadruped control, it remains challenging to ensure robust and compliant locomotion in the presence of unforeseen external disturbances. Existing methods prioritize locomotion robustness over compliance, often leading to stiff, high-frequency motions, and energy inefficiency. This paper, therefore, presents a two-stage hierarchical learning framework that can learn to take active reactions to external force disturbances based on force estimation. In the first stage, a velocity-tracking policy is trained alongside an auto-encoder to distill historical proprioceptive features. A neural network-based estimator is learned through supervised learning, which estimates body velocity and external forces based on proprioceptive measurements. In the second stage, a compliance action module, inspired by impedance control, is learned based on the pre-trained encoder and policy. This module is employed to actively adjust velocity commands in response to external forces based on real-time force estimates. With the compliance action module, a quadruped robot can robustly handle minor disturbances while appropriately yielding to significant forces, thus striking a balance between robustness and compliance. Simulations and real-world experiments have demonstrated that our method has superior performance in terms of robustness, energy efficiency, and safety. Experiment comparison shows that our method outperforms the state-of-the-art RL-based locomotion controllers. Ablation studies are given to show the critical roles of the compliance action module.

Original language	English
Title of host publication	IROS 2025 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, Conference Proceedings
Editors	Christian Laugier, Alessandro Renzaglia, Nikolay Atanasov, Stan Birchfield, Grzegorz Cielniak, Leonardo De Mattos, Laura Fiorini, Philippe Giguere, Kenji Hashimoto, Javier Ibanez-Guzman, Tetsushi Kamegawa, Jinoh Lee, Giuseppe Loianno, Kevin Luck, Hisataka Maruyama, Philippe Martinet, Hadi Moradi, Urbano Nunes, Julien Pettre, Alberto Pretto, Tommaso Ranzani, Arne Ronnau, Silvia Rossi, Elliott Rouse, Fabio Ruggiero, Olivier Simonin, Danwei Wang, Ming Yang, Eiichi Yoshida, Huijing Zhao
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	10649-10655
Number of pages	7
ISBN (Electronic)	9798331543938
DOIs	https://doi.org/10.1109/IROS60139.2025.11247775
State	Published - 2025
Event	2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, IROS 2025 - Hangzhou, China Duration: 19 Oct 2025 → 25 Oct 2025

Publication series

Name	IEEE International Conference on Intelligent Robots and Systems
ISSN (Print)	2153-0858
ISSN (Electronic)	2153-0866

Conference

Conference	2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, IROS 2025
Country/Territory	China
City	Hangzhou
Period	19/10/25 → 25/10/25

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Access to Document

10.1109/IROS60139.2025.11247775

Cite this

Zhou, X., Zhang, X., Wu, T., Zhang, Q., & Zhang, L. (2025). HAC-LOCO: Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances. In C. Laugier, A. Renzaglia, N. Atanasov, S. Birchfield, G. Cielniak, L. De Mattos, L. Fiorini, P. Giguere, K. Hashimoto, J. Ibanez-Guzman, T. Kamegawa, J. Lee, G. Loianno, K. Luck, H. Maruyama, P. Martinet, H. Moradi, U. Nunes, J. Pettre, A. Pretto, T. Ranzani, A. Ronnau, S. Rossi, E. Rouse, F. Ruggiero, O. Simonin, D. Wang, M. Yang, E. Yoshida, ... H. Zhao (Eds.), IROS 2025 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, Conference Proceedings (pp. 10649-10655). (IEEE International Conference on Intelligent Robots and Systems ). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/IROS60139.2025.11247775

Zhou, Xiang ; Zhang, Xinyu ; Wu, Tong et al. / HAC-LOCO : Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances. IROS 2025 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, Conference Proceedings. editor / Christian Laugier ; Alessandro Renzaglia ; Nikolay Atanasov ; Stan Birchfield ; Grzegorz Cielniak ; Leonardo De Mattos ; Laura Fiorini ; Philippe Giguere ; Kenji Hashimoto ; Javier Ibanez-Guzman ; Tetsushi Kamegawa ; Jinoh Lee ; Giuseppe Loianno ; Kevin Luck ; Hisataka Maruyama ; Philippe Martinet ; Hadi Moradi ; Urbano Nunes ; Julien Pettre ; Alberto Pretto ; Tommaso Ranzani ; Arne Ronnau ; Silvia Rossi ; Elliott Rouse ; Fabio Ruggiero ; Olivier Simonin ; Danwei Wang ; Ming Yang ; Eiichi Yoshida ; Huijing Zhao. Institute of Electrical and Electronics Engineers Inc., 2025. pp. 10649-10655 (IEEE International Conference on Intelligent Robots and Systems ).

@inproceedings{87184bcac4fd46a88e3c90e375931738,

title = "HAC-LOCO: Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances",

abstract = "Despite recent remarkable achievements in quadruped control, it remains challenging to ensure robust and compliant locomotion in the presence of unforeseen external disturbances. Existing methods prioritize locomotion robustness over compliance, often leading to stiff, high-frequency motions, and energy inefficiency. This paper, therefore, presents a two-stage hierarchical learning framework that can learn to take active reactions to external force disturbances based on force estimation. In the first stage, a velocity-tracking policy is trained alongside an auto-encoder to distill historical proprioceptive features. A neural network-based estimator is learned through supervised learning, which estimates body velocity and external forces based on proprioceptive measurements. In the second stage, a compliance action module, inspired by impedance control, is learned based on the pre-trained encoder and policy. This module is employed to actively adjust velocity commands in response to external forces based on real-time force estimates. With the compliance action module, a quadruped robot can robustly handle minor disturbances while appropriately yielding to significant forces, thus striking a balance between robustness and compliance. Simulations and real-world experiments have demonstrated that our method has superior performance in terms of robustness, energy efficiency, and safety. Experiment comparison shows that our method outperforms the state-of-the-art RL-based locomotion controllers. Ablation studies are given to show the critical roles of the compliance action module.",

author = "Xiang Zhou and Xinyu Zhang and Tong Wu and Qingrui Zhang and Lixian Zhang",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.; 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, IROS 2025 ; Conference date: 19-10-2025 Through 25-10-2025",

year = "2025",

doi = "10.1109/IROS60139.2025.11247775",

language = "英语",

series = "IEEE International Conference on Intelligent Robots and Systems ",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

pages = "10649--10655",

editor = "Christian Laugier and Alessandro Renzaglia and Nikolay Atanasov and Stan Birchfield and Grzegorz Cielniak and \{De Mattos\}, Leonardo and Laura Fiorini and Philippe Giguere and Kenji Hashimoto and Javier Ibanez-Guzman and Tetsushi Kamegawa and Jinoh Lee and Giuseppe Loianno and Kevin Luck and Hisataka Maruyama and Philippe Martinet and Hadi Moradi and Urbano Nunes and Julien Pettre and Alberto Pretto and Tommaso Ranzani and Arne Ronnau and Silvia Rossi and Elliott Rouse and Fabio Ruggiero and Olivier Simonin and Danwei Wang and Ming Yang and Eiichi Yoshida and Huijing Zhao",

booktitle = "IROS 2025 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, Conference Proceedings",

address = "美国",

}

Zhou, X, Zhang, X, Wu, T, Zhang, Q & Zhang, L 2025, HAC-LOCO: Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances. in C Laugier, A Renzaglia, N Atanasov, S Birchfield, G Cielniak, L De Mattos, L Fiorini, P Giguere, K Hashimoto, J Ibanez-Guzman, T Kamegawa, J Lee, G Loianno, K Luck, H Maruyama, P Martinet, H Moradi, U Nunes, J Pettre, A Pretto, T Ranzani, A Ronnau, S Rossi, E Rouse, F Ruggiero, O Simonin, D Wang, M Yang, E Yoshida & H Zhao (eds), IROS 2025 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, Conference Proceedings. IEEE International Conference on Intelligent Robots and Systems , Institute of Electrical and Electronics Engineers Inc., pp. 10649-10655, 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, IROS 2025, Hangzhou, China, 19/10/25. https://doi.org/10.1109/IROS60139.2025.11247775

HAC-LOCO: Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances. / Zhou, Xiang; Zhang, Xinyu; Wu, Tong et al.
IROS 2025 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, Conference Proceedings. ed. / Christian Laugier; Alessandro Renzaglia; Nikolay Atanasov; Stan Birchfield; Grzegorz Cielniak; Leonardo De Mattos; Laura Fiorini; Philippe Giguere; Kenji Hashimoto; Javier Ibanez-Guzman; Tetsushi Kamegawa; Jinoh Lee; Giuseppe Loianno; Kevin Luck; Hisataka Maruyama; Philippe Martinet; Hadi Moradi; Urbano Nunes; Julien Pettre; Alberto Pretto; Tommaso Ranzani; Arne Ronnau; Silvia Rossi; Elliott Rouse; Fabio Ruggiero; Olivier Simonin; Danwei Wang; Ming Yang; Eiichi Yoshida; Huijing Zhao. Institute of Electrical and Electronics Engineers Inc., 2025. p. 10649-10655 (IEEE International Conference on Intelligent Robots and Systems ).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - HAC-LOCO

T2 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, IROS 2025

AU - Zhou, Xiang

AU - Zhang, Xinyu

AU - Wu, Tong

AU - Zhang, Qingrui

AU - Zhang, Lixian

PY - 2025

Y1 - 2025

N2 - Despite recent remarkable achievements in quadruped control, it remains challenging to ensure robust and compliant locomotion in the presence of unforeseen external disturbances. Existing methods prioritize locomotion robustness over compliance, often leading to stiff, high-frequency motions, and energy inefficiency. This paper, therefore, presents a two-stage hierarchical learning framework that can learn to take active reactions to external force disturbances based on force estimation. In the first stage, a velocity-tracking policy is trained alongside an auto-encoder to distill historical proprioceptive features. A neural network-based estimator is learned through supervised learning, which estimates body velocity and external forces based on proprioceptive measurements. In the second stage, a compliance action module, inspired by impedance control, is learned based on the pre-trained encoder and policy. This module is employed to actively adjust velocity commands in response to external forces based on real-time force estimates. With the compliance action module, a quadruped robot can robustly handle minor disturbances while appropriately yielding to significant forces, thus striking a balance between robustness and compliance. Simulations and real-world experiments have demonstrated that our method has superior performance in terms of robustness, energy efficiency, and safety. Experiment comparison shows that our method outperforms the state-of-the-art RL-based locomotion controllers. Ablation studies are given to show the critical roles of the compliance action module.

AB - Despite recent remarkable achievements in quadruped control, it remains challenging to ensure robust and compliant locomotion in the presence of unforeseen external disturbances. Existing methods prioritize locomotion robustness over compliance, often leading to stiff, high-frequency motions, and energy inefficiency. This paper, therefore, presents a two-stage hierarchical learning framework that can learn to take active reactions to external force disturbances based on force estimation. In the first stage, a velocity-tracking policy is trained alongside an auto-encoder to distill historical proprioceptive features. A neural network-based estimator is learned through supervised learning, which estimates body velocity and external forces based on proprioceptive measurements. In the second stage, a compliance action module, inspired by impedance control, is learned based on the pre-trained encoder and policy. This module is employed to actively adjust velocity commands in response to external forces based on real-time force estimates. With the compliance action module, a quadruped robot can robustly handle minor disturbances while appropriately yielding to significant forces, thus striking a balance between robustness and compliance. Simulations and real-world experiments have demonstrated that our method has superior performance in terms of robustness, energy efficiency, and safety. Experiment comparison shows that our method outperforms the state-of-the-art RL-based locomotion controllers. Ablation studies are given to show the critical roles of the compliance action module.

UR - https://www.scopus.com/pages/publications/105029986918

U2 - 10.1109/IROS60139.2025.11247775

DO - 10.1109/IROS60139.2025.11247775

M3 - 会议稿件

AN - SCOPUS:105029986918

T3 - IEEE International Conference on Intelligent Robots and Systems

SP - 10649

EP - 10655

BT - IROS 2025 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, Conference Proceedings

A2 - Laugier, Christian

A2 - Renzaglia, Alessandro

A2 - Atanasov, Nikolay

A2 - Birchfield, Stan

A2 - Cielniak, Grzegorz

A2 - De Mattos, Leonardo

A2 - Fiorini, Laura

A2 - Giguere, Philippe

A2 - Hashimoto, Kenji

A2 - Ibanez-Guzman, Javier

A2 - Kamegawa, Tetsushi

A2 - Lee, Jinoh

A2 - Loianno, Giuseppe

A2 - Luck, Kevin

A2 - Maruyama, Hisataka

A2 - Martinet, Philippe

A2 - Moradi, Hadi

A2 - Nunes, Urbano

A2 - Pettre, Julien

A2 - Pretto, Alberto

A2 - Ranzani, Tommaso

A2 - Ronnau, Arne

A2 - Rossi, Silvia

A2 - Rouse, Elliott

A2 - Ruggiero, Fabio

A2 - Simonin, Olivier

A2 - Wang, Danwei

A2 - Yang, Ming

A2 - Yoshida, Eiichi

A2 - Zhao, Huijing

PB - Institute of Electrical and Electronics Engineers Inc.

Y2 - 19 October 2025 through 25 October 2025

ER -

Zhou X, Zhang X, Wu T, Zhang Q, Zhang L. HAC-LOCO: Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances. In Laugier C, Renzaglia A, Atanasov N, Birchfield S, Cielniak G, De Mattos L, Fiorini L, Giguere P, Hashimoto K, Ibanez-Guzman J, Kamegawa T, Lee J, Loianno G, Luck K, Maruyama H, Martinet P, Moradi H, Nunes U, Pettre J, Pretto A, Ranzani T, Ronnau A, Rossi S, Rouse E, Ruggiero F, Simonin O, Wang D, Yang M, Yoshida E, Zhao H, editors, IROS 2025 - 2025 IEEE/RSJ International Conference on Intelligent Robots and Systems, Conference Proceedings. Institute of Electrical and Electronics Engineers Inc. 2025. p. 10649-10655. (IEEE International Conference on Intelligent Robots and Systems ). doi: 10.1109/IROS60139.2025.11247775

HAC-LOCO: Learning Hierarchical Active Compliance Control for Quadruped Locomotion under Continuous External Disturbances

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