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Main Authors: Lupu, Elena Sorina, Xie, Fengze, Preiss, James A., Alindogan, Jedidiah, Anderson, Matthew, Chung, Soon-Jo
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.12304
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author Lupu, Elena Sorina
Xie, Fengze
Preiss, James A.
Alindogan, Jedidiah
Anderson, Matthew
Chung, Soon-Jo
author_facet Lupu, Elena Sorina
Xie, Fengze
Preiss, James A.
Alindogan, Jedidiah
Anderson, Matthew
Chung, Soon-Jo
contents Control of off-road vehicles is challenging due to the complex dynamic interactions with the terrain. Accurate modeling of these interactions is important to optimize driving performance, but the relevant physical phenomena are too complex to model from first principles. Therefore, we present an offline meta-learning algorithm to construct a rapidly-tunable model of residual dynamics and disturbances. Our model processes terrain images into features using a visual foundation model (VFM), then maps these features and the vehicle state to an estimate of the current actuation matrix using a deep neural network (DNN). We then combine this model with composite adaptive control to modify the last layer of the DNN in real time, accounting for the remaining terrain interactions not captured during offline training. We provide mathematical guarantees of stability and robustness for our controller and demonstrate the effectiveness of our method through simulations and hardware experiments with a tracked vehicle and a car-like robot. We evaluate our method outdoors on different slopes with varying slippage and actuator degradation disturbances, and compare against an adaptive controller that does not use the VFM terrain features. We show significant improvement over the baseline in both hardware experimentation and simulation.
format Preprint
id arxiv_https___arxiv_org_abs_2407_12304
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle MAGIC-VFM: Meta-learning Adaptation for Ground Interaction Control with Visual Foundation Models
Lupu, Elena Sorina
Xie, Fengze
Preiss, James A.
Alindogan, Jedidiah
Anderson, Matthew
Chung, Soon-Jo
Robotics
Control of off-road vehicles is challenging due to the complex dynamic interactions with the terrain. Accurate modeling of these interactions is important to optimize driving performance, but the relevant physical phenomena are too complex to model from first principles. Therefore, we present an offline meta-learning algorithm to construct a rapidly-tunable model of residual dynamics and disturbances. Our model processes terrain images into features using a visual foundation model (VFM), then maps these features and the vehicle state to an estimate of the current actuation matrix using a deep neural network (DNN). We then combine this model with composite adaptive control to modify the last layer of the DNN in real time, accounting for the remaining terrain interactions not captured during offline training. We provide mathematical guarantees of stability and robustness for our controller and demonstrate the effectiveness of our method through simulations and hardware experiments with a tracked vehicle and a car-like robot. We evaluate our method outdoors on different slopes with varying slippage and actuator degradation disturbances, and compare against an adaptive controller that does not use the VFM terrain features. We show significant improvement over the baseline in both hardware experimentation and simulation.
title MAGIC-VFM: Meta-learning Adaptation for Ground Interaction Control with Visual Foundation Models
topic Robotics
url https://arxiv.org/abs/2407.12304