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Physics-Informed Learning for the Friction Modeling of High-Ratio Harmonic Drives

Ines Sorrentino, Giulio Romualdi, Fabio Bergonti, Giuseppe L’Erario, Silvio Traversaro, Daniele Pucci

Year
2024
Citations
4

Abstract

This paper presents a scalable method for friction identification in robots equipped with electric motors and high-ratio harmonic drives, utilizing Physics-Informed Neural Networks (PINN). This approach eliminates the need for dedicated setups and joint torque sensors by leveraging the robot’s intrinsic model and state data. We present a comprehensive pipeline that includes data acquisition, preprocessing, ground truth generation, and model identification. The effectiveness of the PINN-based friction identification is validated through extensive testing on two different joints of the humanoid robot ergoCub, comparing its performance against traditional static friction models like the Coulomb-viscous and Stribeck-Coulombviscous models. Integrating the identified PINN-based friction models into a two-layer torque control architecture enhances real-time friction compensation. The results demonstrate significant improvements in control performance and reductions in energy losses, highlighting the scalability and robustness of the proposed method, also for application across a large number of joints as in the case of humanoid robots.

Keywords

TorqueHarmonic driveRobustness (evolution)RobotHumanoid robotScalabilityCompensation (psychology)Computer scienceControl engineeringArtificial intelligence

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