Robust adaptive neural control for pure-feedback stochastic nonlinear systems with Prandtl–Ishlinskii hysteresis

“…In this section, the back-stepping design approach is carried out for the reduced system (14), and the design processes are given as follows: Step 1: Let z 1 = x 1 − x 1d be the output tracking error between given reference x 1d and system displacement feedback x 1 . The time derivative of z 1 along the first equation of (14) is…”

“…Remark 6: Pressure sensors are required, in theory, to calculate the non-linear control gain β n which involves R 1 and R 2 (see the definitions of β n , R 1 , and R 2 before (5) and (14)]. In practice, the developed control strategy can be implemented just with the displacement feedback.…”

“…Feedback linearisation method is an effective tool to handle the non-linear problem. Feedback linearisation method achieves the desired dynamics by eliminating the undesired non-linear terms [14,15]. To cope with the problem of parametric uncertainties, the adaptive control schemes have been developed for hydraulic servo systems [16][17][18].…”

Disturbance observer‐based output feedback control of hydraulic servo system considering mismatched uncertainties and internal pressure dynamics stability

“…In this section, the back-stepping design approach is carried out for the reduced system (14), and the design processes are given as follows: Step 1: Let z 1 = x 1 − x 1d be the output tracking error between given reference x 1d and system displacement feedback x 1 . The time derivative of z 1 along the first equation of (14) is…”

“…Remark 6: Pressure sensors are required, in theory, to calculate the non-linear control gain β n which involves R 1 and R 2 (see the definitions of β n , R 1 , and R 2 before (5) and (14)]. In practice, the developed control strategy can be implemented just with the displacement feedback.…”

“…Feedback linearisation method is an effective tool to handle the non-linear problem. Feedback linearisation method achieves the desired dynamics by eliminating the undesired non-linear terms [14,15]. To cope with the problem of parametric uncertainties, the adaptive control schemes have been developed for hydraulic servo systems [16][17][18].…”

Disturbance observer‐based output feedback control of hydraulic servo system considering mismatched uncertainties and internal pressure dynamics stability

“…However, some design parameters are needed further determination. Some scholars have also studied various approaches of control and tracking for systems with PI hysteresis, such as robust adaptive back‐stepping control and adaptive robust output feedback control, and so on 10‐12 …”

Anti‐disturbance adaptive sampled‐data observers for a class of nonlinear systems with unknown hysteresis

“…Due to the instability and performance degradation effects of stochastic disturbances on a system, the control of stochastic nonlinear systems has received much attention in recent years . Therefore, several nonlinear stochastic control techniques including sliding mode, Takagi‐Sugeno (T‐S) fuzzy, and backstepping have been presented. Among the existing methods, the capabilities of the backstepping controller in integrating with nonlinear approximators and stochastic theories to estimate unknown terms and uncertainties and handling the stochastic disturbance input provide an interesting platform for nonlinear control of the stochastic systems.…”

Robust adaptive backstepping tracking control of stochastic nonlinear systems with unknown input saturation: A command filter approach