Active disturbance rejection control strategy for airborne radar stabilization platform based on cascade extended state observer

• Published in: Assembly automation Vol. 40; no. 4; pp. 613 - 624
• Main Authors: Mei, Dong, Yu, Zhu-Qing
• Format: Journal Article
• Language: English
• Published: Bedford Emerald Publishing Limited 17.06.2020; Emerald Group Publishing Limited
• Subjects: Accuracy; Active control; Airborne observation; Airborne radar; Angular position; Angular velocity; Control algorithms; Controllers; Error feedback; Error signals; Friction; Fuzzy logic; Interference; Laplace transforms; Mathematical models; Neural networks; Proportional integral derivative; Radar imaging; Rejection; Stabilization; Stabilized platforms; State observers; Strategy; Velocity; Airborne radar stabilization platform; Active disturbance rejection control; Simulation; Anti-Interference ability; Cascade extended state observer
• ISSN: 0144-5154; 1758-4078
• DOI: 10.1108/AA-10-2019-0178

Purpose This paper aims to improve the anti-interference ability of the airborne radar stabilization platform, especially the ability to suppress continuous disturbance under complex air conditions to ensure the clarity and stability of airborne radar imaging. Design/methodology/approach This paper proposes a new active disturbance rejection control (ADRC) strategy based on the cascade extended state observer (ESO) for airborne radar stabilization platform, which adopts two first-order ESOs to estimate the angular velocity value and the angular position value of the stabilized platform. Then makes the error signal which subtracts the estimated value of ESO from the output signal of the tracking-differentiator as the input signal of the nonlinear state error feedback (NLSEF), and according to the output signal of the NLSEF and the value which dynamically compensated the total disturbances estimated by the two ESO to produce the final control signal. Findings The simulation results show that, compared with the classical ADRC, the ADRC based on the cascade ESO not only estimates the unknown disturbance more accurately but also improves the delay of disturbance observation effectively due to the increase of the order of the observer. In addition, compared with the classical PID control and the classical ADRC, it has made great progress in response performance and anti-interference ability, especially in the complex air conditions. Originality/value The originality of the paper is the adoption of a new ADRC control strategy based on the cascade ESO to ameliorate the anti-interference ability of the airborne radar stabilization platform, especially the ability to suppress continuous interference under complex air conditions.