Optimization algorithms as robust feedback controllers

IF 7.3 2区 计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS
Adrian Hauswirth, Zhiyu He, Saverio Bolognani, Gabriela Hug, Florian Dörfler
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引用次数: 0

Abstract

Mathematical optimization is one of the cornerstones of modern engineering research and practice. Yet, throughout all application domains, mathematical optimization is, for the most part, considered to be a numerical discipline. Optimization problems are formulated to be solved numerically with specific algorithms running on microprocessors. An emerging alternative is to view optimization algorithms as dynamical systems. Besides being insightful in itself, this perspective liberates optimization methods from specific numerical and algorithmic aspects and opens up new possibilities to endow complex real-world systems with sophisticated self-optimizing behavior. Towards this goal, it is necessary to understand how numerical optimization algorithms can be converted into feedback controllers to enable robust “closed-loop optimization”. In this article, we focus on recent control designs under the name of “feedback-based optimization” which implement optimization algorithms directly in closed loop with physical systems. In addition to a brief overview of selected continuous-time dynamical systems for optimization, our particular emphasis in this survey lies on closed-loop stability as well as the robust enforcement of physical and operational constraints in closed-loop implementations. To bypass accessing partial model information of physical systems, we further elaborate on fully data-driven and model-free operations. We highlight an emerging application in autonomous reserve dispatch in power systems, where the theory has transitioned to practice by now. We also provide short expository reviews of pioneering applications in communication networks and electricity grids, as well as related research streams, including extremum seeking and pertinent methods from model predictive and process control, to facilitate high-level comparisons with the main topic of this survey.

作为鲁棒反馈控制器的优化算法
数学优化是现代工程研究和实践的基石之一。然而,在所有应用领域中,数学优化大多被视为一门数值学科。优化问题是通过在微处理器上运行的特定算法进行数值求解的。一种新兴的替代方法是将优化算法视为动态系统。除了本身具有深刻的洞察力之外,这种观点还将优化方法从特定的数值和算法方面解放出来,为复杂的现实世界系统赋予复杂的自我优化行为提供了新的可能性。为实现这一目标,有必要了解如何将数值优化算法转换为反馈控制器,以实现稳健的 "闭环优化"。在本文中,我们将重点介绍以 "基于反馈的优化 "为名的最新控制设计,这些设计直接在物理系统的闭环中实施优化算法。除了对选定的用于优化的连续时间动态系统进行简要概述外,我们还特别强调了闭环稳定性以及在闭环实施中对物理和操作约束的稳健执行。为了避免获取物理系统的部分模型信息,我们进一步阐述了完全数据驱动和无模型的操作。我们重点介绍了电力系统中自主储备调度的新兴应用,目前该理论已过渡到实践中。我们还对通信网络和电网中的开创性应用以及相关研究流(包括极值寻优以及模型预测和过程控制中的相关方法)进行了简短的阐述性回顾,以便于与本调查的主要议题进行高层次比较。
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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来源期刊
Annual Reviews in Control
Annual Reviews in Control 工程技术-自动化与控制系统
CiteScore
19.00
自引率
2.10%
发文量
53
审稿时长
36 days
期刊介绍: The field of Control is changing very fast now with technology-driven “societal grand challenges” and with the deployment of new digital technologies. The aim of Annual Reviews in Control is to provide comprehensive and visionary views of the field of Control, by publishing the following types of review articles: Survey Article: Review papers on main methodologies or technical advances adding considerable technical value to the state of the art. Note that papers which purely rely on mechanistic searches and lack comprehensive analysis providing a clear contribution to the field will be rejected. Vision Article: Cutting-edge and emerging topics with visionary perspective on the future of the field or how it will bridge multiple disciplines, and Tutorial research Article: Fundamental guides for future studies.
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