Abstract
Airline electromechanical actuators (EMAs), on the task of controlling flight surfaces, hold a great promise with the development of more- and all-electric aircraft. Notwithstanding, the deficiencies in both robustness and adaptability of control algorithms prevent EMAs from extensive use. However, the state-of-the-art control schemes fail to precisely compensate the system nonlinear uncertainties of servo control. In this paper, from the innovation point of view, we tend to put forward the foundation of devising an active disturbance rejection robust adaptive control (ADRRAC) strategy, whose main purpose is to deal with the position servo control of EMA. Specifically, an adaptive control law is designed and deployed for resolving not only the nonlinear disturbance, but also the parameter uncertainties. In addition, an extended disturbance estimator is employed to estimate the external disturbance and thus eliminate its impact. The proposed controlling algorithm is deemed best able to address the external disturbance based on the nonlinear uncertainty compensation. With the input parameters and control commands, the ADRRAC strategy maintains servo system stability while approaching the controlling target. Following the algorithm description, a proof of the controlling stability of ADRRAC strategy is presented in detail as well. Experiments on a variety of tracking tasks are conducted on a prototype of an EMA to investigate the working performance of the proposed control strategy. The experimental outcomes are reported, which verify the effectiveness of the ADRRAC strategy, compared to widely applied control strategies. According to the data analysis results, our controller is capable of obtaining an even faster system response, a higher tracking accuracy and a more stable system state.
Highlights
Actuation systems for more electrical aircraft must balance requirements of high power, light weight, safety, fast response and continuity of service
Electromechanical actuators (EMAs) are considered as a leap forward and receive interest because of their higher efficiency and reduction in both weight and maintenance time compared with hydraulic actuators [2,3,4]
In line with the control strategy design process, research on electromechanical actuators (EMAs) focuses on the use of the state-of-the-art controllers
Summary
Actuation systems for more electrical aircraft must balance requirements of high power, light weight, safety, fast response and continuity of service. Wrat et al applied a synthesized position control strategy to ensure the working performance under model uncertainties and dynamical load disturbance [18]. According to [19], strong robust control of uncertainties of an EMA on aircraft is critical for handling parameter perturbation and load disturbance. An active disturbance rejection robust adaptive control (ADRRAC) strategy is dedicatedly designed and deployed, targeting at addressing the position servo issues in EMA control. To this end, the nonlinear uncertainties of the system, together with their compensation, are integrated into the control strategy as well.
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