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Autori principali: Cheng, Jing, Alqaham, Yasser G., Sanyal, Amit K., Gan, Zhenyu
Natura: Preprint
Pubblicazione: 2022
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Accesso online:https://arxiv.org/abs/2211.11922
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author Cheng, Jing
Alqaham, Yasser G.
Sanyal, Amit K.
Gan, Zhenyu
author_facet Cheng, Jing
Alqaham, Yasser G.
Sanyal, Amit K.
Gan, Zhenyu
contents Precise trajectory tracking for legged robots can be challenging due to their high degrees of freedom, unmodeled nonlinear dynamics, or random disturbances from the environment. A commonly adopted solution to overcome these challenges is to use optimization-based algorithms and approximate the system with a simplified, reduced-order model. Additionally, deep neural networks are becoming a more promising option for achieving agile and robust legged locomotion. These approaches, however, either require large amounts of onboard calculations or the collection of millions of data points from a single robot. To address these problems and improve tracking performance, this paper proposes a method based on iterative learning control. This method lets a robot learn from its own mistakes by exploiting the repetitive nature of legged locomotion within only a few trials. Then, a torque library is created as a lookup table so that the robot does not need to repeat calculations or learn the same skill over and over again. This process resembles how animals learn their muscle memories in nature. The proposed method is tested on the A1 robot in a simulated environment, and it allows the robot to pronk at different speeds while precisely following the reference trajectories without heavy calculations.
format Preprint
id arxiv_https___arxiv_org_abs_2211_11922
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Practice Makes Perfect: an iterative approach to achieve precise tracking for legged robots
Cheng, Jing
Alqaham, Yasser G.
Sanyal, Amit K.
Gan, Zhenyu
Robotics
I.2.9
Precise trajectory tracking for legged robots can be challenging due to their high degrees of freedom, unmodeled nonlinear dynamics, or random disturbances from the environment. A commonly adopted solution to overcome these challenges is to use optimization-based algorithms and approximate the system with a simplified, reduced-order model. Additionally, deep neural networks are becoming a more promising option for achieving agile and robust legged locomotion. These approaches, however, either require large amounts of onboard calculations or the collection of millions of data points from a single robot. To address these problems and improve tracking performance, this paper proposes a method based on iterative learning control. This method lets a robot learn from its own mistakes by exploiting the repetitive nature of legged locomotion within only a few trials. Then, a torque library is created as a lookup table so that the robot does not need to repeat calculations or learn the same skill over and over again. This process resembles how animals learn their muscle memories in nature. The proposed method is tested on the A1 robot in a simulated environment, and it allows the robot to pronk at different speeds while precisely following the reference trajectories without heavy calculations.
title Practice Makes Perfect: an iterative approach to achieve precise tracking for legged robots
topic Robotics
I.2.9
url https://arxiv.org/abs/2211.11922