Fault Accommodation in Control of Flexible Systems

New synthesis techniques for the design of fault accommodating control systems for flexible systems are developed. Three robust control design strategies; static dissipative, dynamic dissipative and mu synthesis control designs are used in the approach. The approach provides techniques for designing controllers that maximize, in some sense, the tolerance of the closed-loop system against faults in actuators and sensors, while guaranteeing performance robustness at a specified performance level, measured in terms of the proximity of the closed-loop poles to the imaginary axis (the degree of stability). For dissipative control designs, nonlinear programming is employed to synthesize the controllers, whereas in mu-synthesis, the traditional D-K iteration is used. In order to demonstrate the feasibility of the proposed techniques, they are applied to the control design of a flexible laboratory test structure.