控制理论(社会学)
模型预测控制
稳健性(进化)
非线性系统
二次方程
参数化(大气建模)
仿射变换
线性系统
计算机科学
正多边形
凸优化
数学优化
数学
控制(管理)
人工智能
数学分析
生物化学
化学
物理
几何学
量子力学
辐射传输
纯数学
基因
作者
Julian Berberich,Johannes Köhler,Matthias A. Müller,Frank Allgöwer
标识
DOI:10.1109/tac.2022.3166851
摘要
In this article, we present a novel data-driven model predictive control (MPC) approach to control unknown nonlinear systems using only measured input–output data with closed-loop stability guarantees. Our scheme relies on the data-driven system parameterization provided by the fundamental lemma of Willems et al. We use new input–output measurements online to update the data, exploiting local linear approximations of the underlying system. We prove that our MPC scheme, which only requires solving strictly convex quadratic programs online, ensures that the closed loop (practically) converges to the (unknown) optimal reachable equilibrium that tracks a desired output reference while satisfying polytopic input constraints. As intermediate results of independent interest, we extend the fundamental lemma to affine systems and we derive novel robustness bounds w.r.t. noisy data for the open-loop optimal control problem, which are directly transferable to other data-driven MPC schemes in the literature. The applicability of our approach is illustrated with a numerical application to a continuous stirred tank reactor.
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