Robust and Gain-Scheduling H2 Control Techniques for LFT Uncertain and Parameter-Dependent Systems

Abstract

This paper addresses the robust H2 synthesis problem for linear fractional transformation (LFT) systems subject to structured uncertainty (parameter) and white-noise disturbances. By introducing an intermediate matrix variable, we derive convex synthesis conditions in terms of linear matrix inequalities (LMIs) that enable both robust and gain-scheduled controller design for parameter-dependent systems. The proposed framework preserves the classical white-noise and impulse-response interpretation of the H2 criterion while providing certified robustness guarantees, thereby extending optimal H2 control beyond the linear time-invariant setting. Numerical and application examples demonstrate that the resulting robust H2 controllers achieve significantly reduced conservatism and improved disturbance rejection compared with conventional robust H∞-based designs.