Guaranteed Trajectory Tracking under Learned Dynamics with Contraction Metrics and Disturbance Estimation

Pan Zhao; Ziyao Guo; Yikun Cheng; Aditya Gahlawat; Hyungsoo Kang; Naira Hovakimyan

doi:10.3390/robotics13070099

Guaranteed Trajectory Tracking under Learned Dynamics with Contraction Metrics and Disturbance Estimation

Pan Zhao, Ziyao Guo, Yikun Cheng, Aditya Gahlawat, Hyungsoo Kang, Naira Hovakimyan

Research output: Contribution to journal › Article › peer-review

Abstract

This paper presents a contraction-based learning control architecture that allows for using model learning tools to learn matched model uncertainties while guaranteeing trajectory tracking performance during the learning transients. The architecture relies on a disturbance estimator to estimate the pointwise value of the uncertainty, i.e., the discrepancy between a nominal model and the true dynamics, with pre-computable estimation error bounds, and a robust Riemannian energy condition for computing the control signal. Under certain conditions, the controller guarantees exponential trajectory convergence during the learning transients, while learning can improve robustness and facilitate better trajectory planning. Simulation results validate the efficacy of the proposed control architecture.

Original language	English (US)
Article number	99
Journal	Robotics
Volume	13
Issue number	7
Early online date	Jun 30 2024
DOIs	https://doi.org/10.3390/robotics13070099
State	Published - Jul 2024

Keywords

robust control
robot safety
machine learning for control
decision-making under uncertainty

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10.3390/robotics13070099License: CC BY

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title = "Guaranteed Trajectory Tracking under Learned Dynamics with Contraction Metrics and Disturbance Estimation",

abstract = "This paper presents a contraction-based learning control architecture that allows for using model learning tools to learn matched model uncertainties while guaranteeing trajectory tracking performance during the learning transients. The architecture relies on a disturbance estimator to estimate the pointwise value of the uncertainty, i.e., the discrepancy between a nominal model and the true dynamics, with pre-computable estimation error bounds, and a robust Riemannian energy condition for computing the control signal. Under certain conditions, the controller guarantees exponential trajectory convergence during the learning transients, while learning can improve robustness and facilitate better trajectory planning. Simulation results validate the efficacy of the proposed control architecture.",

keywords = "robust control, robot safety, machine learning for control, decision-making under uncertainty",

author = "Pan Zhao and Ziyao Guo and Yikun Cheng and Aditya Gahlawat and Hyungsoo Kang and Naira Hovakimyan",

note = "This research was funded in part by NASA through the ULI grant #80NSSC22M0070, and in part by NSF under the RI grant #2133656.",

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language = "English (US)",

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journal = "Robotics",

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T1 - Guaranteed Trajectory Tracking under Learned Dynamics with Contraction Metrics and Disturbance Estimation

AU - Zhao, Pan

AU - Guo, Ziyao

AU - Cheng, Yikun

AU - Gahlawat, Aditya

AU - Kang, Hyungsoo

AU - Hovakimyan, Naira

N1 - This research was funded in part by NASA through the ULI grant #80NSSC22M0070, and in part by NSF under the RI grant #2133656.

PY - 2024/7

Y1 - 2024/7

N2 - This paper presents a contraction-based learning control architecture that allows for using model learning tools to learn matched model uncertainties while guaranteeing trajectory tracking performance during the learning transients. The architecture relies on a disturbance estimator to estimate the pointwise value of the uncertainty, i.e., the discrepancy between a nominal model and the true dynamics, with pre-computable estimation error bounds, and a robust Riemannian energy condition for computing the control signal. Under certain conditions, the controller guarantees exponential trajectory convergence during the learning transients, while learning can improve robustness and facilitate better trajectory planning. Simulation results validate the efficacy of the proposed control architecture.

AB - This paper presents a contraction-based learning control architecture that allows for using model learning tools to learn matched model uncertainties while guaranteeing trajectory tracking performance during the learning transients. The architecture relies on a disturbance estimator to estimate the pointwise value of the uncertainty, i.e., the discrepancy between a nominal model and the true dynamics, with pre-computable estimation error bounds, and a robust Riemannian energy condition for computing the control signal. Under certain conditions, the controller guarantees exponential trajectory convergence during the learning transients, while learning can improve robustness and facilitate better trajectory planning. Simulation results validate the efficacy of the proposed control architecture.

KW - robust control

KW - robot safety

KW - machine learning for control

KW - decision-making under uncertainty

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Guaranteed Trajectory Tracking under Learned Dynamics with Contraction Metrics and Disturbance Estimation

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