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Accuracy and Safety: Tracking Control of Heavy-Duty Cooperative Transportation Systems Using Constraint-Following Method | IEEE Journals & Magazine | IEEE Xplore
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Journals & Magazines >IEEE Transactions on Intellig... >Volume: 25 Issue: 5

Accuracy and Safety: Tracking Control of Heavy-Duty Cooperative Transportation Systems Using Constraint-Following Method

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Bowei Zhang; Ye-Hwa Chen; Yifan Jia; Jin Huang; Diange Yang; Zhihua Zhong
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Abstract:

Accurate tracking control of autonomous cooperative transportation systems (CTS) remains challenging owing to the complexity of the mechanisms and the high requirements o...Show More

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Abstract:

Accurate tracking control of autonomous cooperative transportation systems (CTS) remains challenging owing to the complexity of the mechanisms and the high requirements of coordination between carriers. In this paper, the trajectory tracking control of a CTS with a pair of autonomous vehicles serving as carriers is investigated. A novel constraint-oriented hierarchical modeling method is proposed to describe the dynamics of the system. By dividing the system dynamics into two portions: the lower-level individual modeling and the upper-level constraints abstraction, the modeling process is significantly simplified. Then an innovative constraint-following control law is designed to address the tracking control problem under the special system topology, based on the internal and external constraints designed in the modeling process. The asymptotic convergence of the tracking error is theoretically guaranteed. To reduce potential damage of the payload during transportation, a payload force optimization method is creatively proposed. It relies on the closed-form relationship between the control input and payload forces established by the constraint-oriented modeling. The normal and shear stress on the payload is successfully limited, without affecting the trajectory tracking performance. Simulation results show that the proposed control method and the payload force optimization strategy can help achieve accurate and safe autonomous cooperative transportation simultaneously.
Published in: IEEE Transactions on Intelligent Transportation Systems ( Volume: 25, Issue: 5, May 2024)
Page(s): 3628 - 3641
Date of Publication: 13 February 2024

ISSN Information:

DOI: 10.1109/TITS.2023.3335290

Funding Agency:

References is not available for this document.
Contents

I. Introduction

Heavy-duty transportation has a wide range of applications, including the transportation of prefabricated buildings in the construction industry, heavy rockets in the aerospace industry, and large energy storage equipment in the energy industry, etc. [1]. It is challenging for a single carrier with low capacity to transport an oversized heavy payload. To solve the problem, the cooperative transportation strategy is developed to provide adequate carrying ability (Fig. 1). With the flourishing of the autonomous driving technology, lots of studies focused on autonomous multi-agent cooperative transportation in the past few decades [2], [3], [4]. Through caging [5], [6], grasping [7], [8] or being articulated [9] on the payload with different types of end-effectors, carriers form a cooperative transportation system (CTS) with the payload.

Typical cooperative heavy-duty transport cases.

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