面向时变延迟主动车辆悬架控制系统的未知系统动力学估计器

Unknown System Dynamics Estimator for Active Vehicle Suspension Control Systems With Time-Varying Delay

IEEE Transactions on Cybernetics · 2021
被引 69
ABS 3

中文导读

提出一种仅含一个可调参数的低通滤波估计器,无需神经网络等函数逼近器,结合预测器补偿时变输入延迟,用于主动悬架减振并保证性能,仿真验证了有效性。

Abstract

This article proposes a novel control method for vehicle active suspension systems in the presence of time-varying input delay and unknown nonlinearities. An unknown system dynamics estimator (USDE), which employs first-order low-pass filter operations and has only one tuning parameter, is constructed to deal with unknown nonlinearities. With this USDE, the widely used function approximators (e.g., neural networks and fuzzy-logic systems) are not needed, and the intermediate variables and observer used in the traditional estimators are not required. This estimator has a reduced computational burden, trivial parameter tuning and guaranteed convergence. Moreover, a predictor-based compensation strategy is developed to handle the time-varying input delay. Finally, we combine the suggested USDE and predictor to design a feedback controller to attenuate the vibrations of vehicle body and retain the required suspension performances. Theoretical analysis is carried out via the Lyapunov-Krasovkii functional to prove the stability of the closed-loop system. Simulation results based on professional vehicle simulation software Carsim are provided to show the efficiency of the proposed control scheme.

车辆工程主动悬架控制时滞系统非线性估计