模型预测控制
控制理论(社会学)
解算器
理论(学习稳定性)
数学优化
最优化问题
非线性系统
计算机科学
采样(信号处理)
线性系统
采样时间
数学
控制(管理)
物理
人工智能
数学分析
机器学习
滤波器(信号处理)
统计
量子力学
计算机视觉
作者
Dominic Liao‐McPherson,Terrence Skibik,Jordan Leung,Ilya Kolmanovsky,Marco M. Nicotra
标识
DOI:10.1109/tac.2021.3086295
摘要
Time-distributed Optimization (TDO) is an approach for reducing the computational burden of Model Predictive Control (MPC). When using TDO, optimization iterations are distributed over time by maintaining a running solution estimate and updating it at each sampling instant. In this paper, TDO applied to input constrained linear MPC is studied in detail, and analytic expressions for the system gains and a bound on the number of optimization iterations per sampling instant required to guarantee closed-loop stability is derived. Further, it is shown that the closed-loop stability of TDO-based MPC can be guaranteed using multiple mechanisms including increasing the number of solver iterations, preconditioning the optimal control problem, adjusting the MPC cost matrices, and reducing the length of the receding horizon. These results in a linear system setting also provide insights and guidelines that could be more broadly applicable, e.g., to nonlinear MPC.
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