Robust Control Co-Design using Tube-Based Model Predictive Control

2023 American Control Conference (ACC) Pub Date : 2023-05-31 DOI:10.23919/ACC55779.2023.10156303

Ying-Kuan Tsai, R. Malak

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引用次数: 1

Abstract

Control co-design (CCD) has received much attention since it can achieve superior system performance by optimizing physical and control systems simultaneously. Despite many successful examples from diverse engineering fields using CCD, a lack of attention toward accounting for uncertainty hinders application to real-world systems. This paper aims to solve CCD problems under uncertainty by proposing a robust CCD formulation and algorithm. A robust feedback controller using tube-based model predictive control (tube-based MPC) approach is incorporated into a bi-level optimization architecture. The use of the set invariance theory and an approximation algorithm helps identify the set of all possible states due to disturbances, this set is known as a tube, and quantify system robustness by calculating the tube size. It enables designers to make performance-robustness trade-offs with the approximate Pareto fronts. A numerical example and a simplified model of the satellite attitude control system are used to demonstrate the proposed method. Results show that the CCD solutions dominate most of the solutions from the traditional sequential design and control design only. This study will be extended into nonlinear applications in our future work.

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基于管型模型预测控制的鲁棒控制协同设计

控制协同设计(CCD)由于能够同时优化物理系统和控制系统，从而获得优越的系统性能而受到广泛关注。尽管CCD在不同的工程领域有许多成功的例子，但缺乏对不确定性的关注阻碍了其在现实系统中的应用。本文旨在通过提出一种鲁棒的CCD公式和算法，解决不确定条件下的CCD问题。采用基于管的模型预测控制(tube-based MPC)方法的鲁棒反馈控制器被纳入双层优化体系结构中。使用集合不变性理论和近似算法有助于识别由于干扰而产生的所有可能状态的集合，该集合称为管，并通过计算管的大小来量化系统的鲁棒性。它使设计人员能够在近似帕累托前沿进行性能-鲁棒性权衡。最后以卫星姿态控制系统的数值算例和简化模型为例进行了验证。结果表明，CCD解决方案在传统的顺序设计和控制设计中占主导地位。本研究将在今后的工作中扩展到非线性应用领域。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2023 American Control Conference (ACC)

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