Kernel Methods and Gaussian Processes for System Identification and Control: A Road Map on Regularized Kernel-Based Learning for Control

IF 3.9 3区 计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS
Algo Carè, Ruggero Carli, Alberto Dalla Libera, Diego Romeres, Gianluigi Pillonetto
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引用次数: 0

Abstract

The commonly adopted route to control a dynamic system and make it follow the desired behavior consists of two steps. First, a model of the system is learned from input–output data, a task known as system identification in the engineering literature. Here, an important point is not only to derive a nominal model of the plant but also confidence bounds around it. The information coming from the first step is then exploited to design a controller that should guarantee a certain performance also under the uncertainty affecting the model. This classical way to control dynamic systems has recently been the subject of new intense research, thanks to an interesting cross-fertilization with the field of machine learning. New system identification and control techniques have been developed with links to function estimation and mathematical foundations in reproducing kernel Hilbert spaces (RKHSs) and Gaussian processes (GPs). This has become known as the Gaussian regression (kernel-based) approach to system identification and control . It is the purpose of this article to give an overview of this development (see “Summary”).
系统辨识与控制的核方法与高斯过程:正则化核学习控制的路线图
通常采用的控制动态系统并使其遵循期望行为的途径包括两个步骤。首先,从输入输出数据中学习系统的模型,在工程文献中称为系统识别的任务。在这里,重要的一点是不仅要推导出工厂的名义模型,而且要推导出它周围的置信限。然后利用来自第一步的信息来设计控制器,该控制器在不确定性影响模型的情况下也应保证一定的性能。由于与机器学习领域的有趣交叉,这种控制动态系统的经典方法最近成为了新的激烈研究的主题。新的系统识别和控制技术已经发展与函数估计和数学基础在核希尔伯特空间(RKHSs)和高斯过程(GPs)的再现。这被称为系统识别和控制的高斯回归(基于核的)方法。本文的目的是概述这一开发(请参阅“摘要”)。
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
IEEE Control Systems Magazine
IEEE Control Systems Magazine 工程技术-自动化与控制系统
CiteScore
3.70
自引率
5.30%
发文量
137
审稿时长
>12 weeks
期刊介绍: As the official means of communication for the IEEE Control Systems Society, the IEEE Control Systems Magazine publishes interesting, useful, and informative material on all aspects of control system technology for the benefit of control educators, practitioners, and researchers.
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