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Autori principali: Li, Jianwen, Park, Hyunsang, Hao, Wenjian, Xin, Lei, Chavez-Galaviz, Jalil, Chaudhary, Ajinkya, Bloss, Meredith, Pattison, Kyle, Vo, Christopher, Upadhyay, Devesh, Sundaram, Shreyas, Mou, Shaoshuai, Mahmoudian, Nina
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2403.05972
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author Li, Jianwen
Park, Hyunsang
Hao, Wenjian
Xin, Lei
Chavez-Galaviz, Jalil
Chaudhary, Ajinkya
Bloss, Meredith
Pattison, Kyle
Vo, Christopher
Upadhyay, Devesh
Sundaram, Shreyas
Mou, Shaoshuai
Mahmoudian, Nina
author_facet Li, Jianwen
Park, Hyunsang
Hao, Wenjian
Xin, Lei
Chavez-Galaviz, Jalil
Chaudhary, Ajinkya
Bloss, Meredith
Pattison, Kyle
Vo, Christopher
Upadhyay, Devesh
Sundaram, Shreyas
Mou, Shaoshuai
Mahmoudian, Nina
contents In this paper, we discuss the development and deployment of a robust autonomous system capable of performing various tasks in the maritime domain under unknown dynamic conditions. We investigate a data-driven approach based on modular design for ease of transfer of autonomy across different maritime surface vessel platforms. The data-driven approach alleviates issues related to a priori identification of system models that may become deficient under evolving system behaviors or shifting, unanticipated, environmental influences. Our proposed learning-based platform comprises a deep Koopman system model and a change point detector that provides guidance on domain shifts prompting relearning under severe exogenous and endogenous perturbations. Motion control of the autonomous system is achieved via an optimal controller design. The Koopman linearized model naturally lends itself to a linear-quadratic regulator (LQR) control design. We propose the C3D control architecture Cascade Control with Change Point Detection and Deep Koopman Learning. The framework is verified in station keeping task on an ASV in both simulation and real experiments. The approach achieved at least 13.9 percent improvement in mean distance error in all test cases compared to the methods that do not consider system changes.
format Preprint
id arxiv_https___arxiv_org_abs_2403_05972
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle C3D: Cascade Control with Change Point Detection and Deep Koopman Learning for Autonomous Surface Vehicles
Li, Jianwen
Park, Hyunsang
Hao, Wenjian
Xin, Lei
Chavez-Galaviz, Jalil
Chaudhary, Ajinkya
Bloss, Meredith
Pattison, Kyle
Vo, Christopher
Upadhyay, Devesh
Sundaram, Shreyas
Mou, Shaoshuai
Mahmoudian, Nina
Robotics
In this paper, we discuss the development and deployment of a robust autonomous system capable of performing various tasks in the maritime domain under unknown dynamic conditions. We investigate a data-driven approach based on modular design for ease of transfer of autonomy across different maritime surface vessel platforms. The data-driven approach alleviates issues related to a priori identification of system models that may become deficient under evolving system behaviors or shifting, unanticipated, environmental influences. Our proposed learning-based platform comprises a deep Koopman system model and a change point detector that provides guidance on domain shifts prompting relearning under severe exogenous and endogenous perturbations. Motion control of the autonomous system is achieved via an optimal controller design. The Koopman linearized model naturally lends itself to a linear-quadratic regulator (LQR) control design. We propose the C3D control architecture Cascade Control with Change Point Detection and Deep Koopman Learning. The framework is verified in station keeping task on an ASV in both simulation and real experiments. The approach achieved at least 13.9 percent improvement in mean distance error in all test cases compared to the methods that do not consider system changes.
title C3D: Cascade Control with Change Point Detection and Deep Koopman Learning for Autonomous Surface Vehicles
topic Robotics
url https://arxiv.org/abs/2403.05972