Reliable nonlinear control system design using duplicated control elements

Abstract: Reliable L2 gain bounding (i.e., H∞) controllers for nonlinear systems are designed by using redundant control elements. One sensor and one actuator are duplicated, and the resulting closed‐loop system is reliable with respect to both the single contingency case and the primary contingency case. The design procedures for reliable controllers are developed by using the Hamilton–Jacobi inequalities from nonlinear H∞ control theory. Linear reliable controller design methods are also obtained by restricting the pr… Show more

“…are satisfied. By Schur complement, ( 34) and ( 35) are equivalent to (20) and ( 21), so the proof is completed.…”

“…The fault-tolerant-control model ( 4) contains an inaccurate output of the actuator, in addition to the interruption and the normal one. Thus, it covers the fault models in [20] and [35], in which the sensor and actuator fault is a discrete error model.…”

Frequency domain $ H_{\infty} $ control design for active suspension systems

“…are satisfied. By Schur complement, ( 34) and ( 35) are equivalent to (20) and ( 21), so the proof is completed.…”

“…The fault-tolerant-control model ( 4) contains an inaccurate output of the actuator, in addition to the interruption and the normal one. Thus, it covers the fault models in [20] and [35], in which the sensor and actuator fault is a discrete error model.…”

Frequency domain $ H_{\infty} $ control design for active suspension systems

Reliable H∞ fuzzy control for fault-tolerant actuator failures of active suspension system

Reliable H∞ controller design for linear systems