控制理论(社会学)
代数Riccati方程
线性二次调节器
强化学习
参数化(大气建模)
Riccati方程
贝尔曼方程
动态规划
最优控制
计算机科学
输出反馈
理论(学习稳定性)
离散时间和连续时间
国家(计算机科学)
数学
数学优化
控制(管理)
算法
微分方程
辐射传输
统计
机器学习
物理
数学分析
人工智能
量子力学
作者
Syed Ali Asad Rizvi,Zongli Lin
标识
DOI:10.1109/tcyb.2018.2886735
摘要
In this paper, we propose a model-free solution to the linear quadratic regulation (LQR) problem of continuous-time systems based on reinforcement learning using dynamic output feedback. The design objective is to learn the optimal control parameters by using only the measurable input-output data, without requiring model information. A state parametrization scheme is presented which reconstructs the system state based on the filtered input and output signals. Based on this parametrization, two new output feedback adaptive dynamic programming Bellman equations are derived for the LQR problem based on policy iteration and value iteration (VI). Unlike the existing output feedback methods for continuous-time systems, the need to apply discrete approximation is obviated. In contrast with the static output feedback controllers, the proposed method can also handle systems that are state feedback stabilizable but not static output feedback stabilizable. An advantage of this scheme is that it stands immune to the exploration bias issue. Moreover, it does not require a discounted cost function and, thus, ensures the closed-loop stability and the optimality of the solution. Compared with earlier output feedback results, the proposed VI method does not require an initially stabilizing policy. We show that the estimates of the control parameters converge to those obtained by solving the LQR algebraic Riccati equation. A comprehensive simulation study is carried out to verify the proposed algorithms.
科研通智能强力驱动
Strongly Powered by AbleSci AI