高超声速飞行器再入段LQR自抗扰控制方法设计

针对高超声速飞行器(HSV)再入过程中强非线性、强耦合、气动参数变化剧烈的不确定性的特点，提出一种基于线性二次型调节器(LQR)和自抗扰控制(ADRC)的高超声速飞行器再入段的姿态控制方法。首先，建立高超声速飞行器再入段线性化模型，并采用LQR方法完成了状态反馈控制律设计。然后，结合自抗扰控制技术，设计了扩张状态观测器(ESO)对系统的模型不确定性和外部干扰进行补偿，大幅增强了系统的扰动抑制能力。最后，将得到的高超声速飞行器再入段LQR自抗扰姿态控制器(LQRADRC)应用于高超声速飞行器六自由度仿真，仿真结果表明本文所提出的控制方法能够快速、精确地跟踪角位置指令，并且对系统不确定性具有强鲁棒性。

LQR Active Disturbance Rejection Control Method Design for Hypersonic Vehicles in Reentry Phase

Hypersonic vehicle (HSV) has strong nonlinearity, high coupling and multiple variables in the reentry process, bringing challenges for the attitude controller design. This paper investigates a compound control scheme combined with the advantages of the linear quadratic regulator (LQR) and active disturbance rejection control (ADRC) method for the reentry flight attitude control of HSV. Firstly, the HSV 6 degree of freedom model is established. Then the LQR control method is used for the reentry attitude control of the HSV. After that, the basic active disturbance rejection control (ADRC) method is built, and the extended state observer (ESO) is designed to make compensation for the uncertainty of the model. The LQRADRC method for the HSV is firstly proposed. Finally, the simulation results are shown to illustrate the advantages of the proposed LQRADRC method in terms of accuracy and robustness with uncertain parameters.