Disturbance sensitivity analysis and experimental evaluation of continuous sliding mode control

Continuous higher order sliding mode (CHOSM) controllers are new efficient tool for disturbance rejection. For the systems with relative degree r, CHOSM provide theoretically exact compensation of Lipschitz matched perturbation ensuring the finite-time convergence to the (r+1)-th sliding-mode set using only information on the sliding output and its derivatives up to the order (r-1). In this paper, we investigate the properties of disturbance rejection for a PID-like controller, as the simplest and intuitively clear example of CHOSM one, allowing a harmonic balance-based consideration of the residual steady-state oscillations, i.e. chattering. We provide additional analysis of the PID-like controller based on its analytic describing function and the disturbance sensitivity function, allowing certain comparability with the standard linear PID control in frequency domain. For comparison reason a simple and straightforward design procedure for robust PID controller, which is served by the assumed upper bound of the disturbance sensitivity function, is developed. A detailed experimental case study, accomplished on an electro-mechanical actuator in the laboratory setting, highlight and make the pros and cons of both PID and CHOSM controllers well comparable for a broadband disturbance rejection.