SATA: Safe and Adaptive Torque-Based Locomotion Policies Inspired by Animal Learning

Li Peizhuo; Hongyi Li; Ge Sun; Jin Cheng; Xinrong Yang; Guillaume Bellegarda; Milad Shafiee Ashtiani; Yuhong Cao; Auke Ijspeert; Guillaume Adrien Sartoretti

Robotics: Science and Systems XXI

SATA: Safe and Adaptive Torque-Based Locomotion Policies Inspired by Animal Learning

Li Peizhuo, Hongyi Li, Ge Sun, Jin Cheng, Xinrong Yang, Guillaume Bellegarda, Milad Shafiee Ashtiani, Yuhong Cao, Auke Ijspeert, Guillaume Adrien Sartoretti

Abstract:

Despite recent advances in learning-based controllers for legged robots, deployments in human-centric environments remain limited by safety concerns. Most of these approaches use position-based control, where policies output target joint angles that must be processed by a low-level controller (e.g., PD or impedance controllers) to compute joint torques. Although impressive results have been achieved in controlled real-world scenarios, these methods often struggle with compliance and adaptability when encountering environments or disturbances unseen during training, potentially resulting in extreme or unsafe behaviors. Inspired by how animals achieve smooth and adaptive movements by controlling muscle extension and contraction, torque-based policies offer a promising alternative by enabling precise and direct control of the actuators in torque space. In principle, this approach facilitates more effective interactions with the environment, resulting in safer and more adaptable behaviors. However, challenges such as a highly nonlinear state space and inefficient exploration during training have hindered their broader adoption. To address these limitations, we propose Safe and Adaptive Torque-based locomotion policies inspired by Animal learning(SATA), a bio-inspired framework that mimics key biomechanical principles and adaptive learning mechanisms observed in animal locomotion. Our approach effectively addresses the inherent challenges of learning torque-based policies by significantly improving early-stage exploration, leading to high-performance final policies. Remarkably, our method achieves zero-shot sim-to-real transfer, eliminating the need for additional fine-tuning on hardware. Our experimental results indicate that SATA demonstrates remarkable compliance and safety, even in challenging environments such as soft/slippery terrain or narrow passages, and under significant external disturbances (e.g., pushing/pulling/pressing on the robot, or manually moving individual legs). These results highlight its potential for practical deployments in human-centric and safety-critical scenarios.

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Bibtex:

  
@INPROCEEDINGS{PeizhuoL-RSS-25, 
    AUTHOR    = {Li Peizhuo AND Hongyi Li AND Ge Sun AND Jin Cheng AND Xinrong Yang AND Guillaume Bellegarda AND Milad Shafiee Ashtiani AND Yuhong Cao AND Auke Ijspeert AND Guillaume Adrien Sartoretti}, 
    TITLE     = {{SATA: Safe and Adaptive Torque-Based Locomotion Policies Inspired by Animal Learning}}, 
    BOOKTITLE = {Proceedings of Robotics: Science and Systems}, 
    YEAR      = {2025}, 
    ADDRESS   = {LosAngeles, CA, USA}, 
    MONTH     = {June}, 
    DOI       = {10.15607/RSS.2025.XXI.124} 
}