A benchmark problem for nonlinear control design

In this paper we develop a robust controller design for the Active Mass Driver (AMD) benchmark problem. The design process is based around the D-K iteration procedure for (complex) synthesis, together with a balanced truncation procedure to reduce the controller order. The final design is a third-or

This paper outlines a general approach for the design of H dynamic output feedback controllers and applies this method to designing controllers for the Active Mass Driver (AMD) benchmark problem. The example controllers designed for this problem use acceleration output feedback of the structure coup

In this work we give a methodology for controller design and analysis which accounts for design criteria such as: (a) optimal system response to external disturbances, (b) robustness to modelling uncertainty, and (c) constraints on the controller order. The methodology is applied to a structural con

This study investigates the use of H , -synthesis, and mixed H / methods to construct full-order controllers and optimized controllers of fixed dimensions. The benchmark problem definition is first extended to include uncertainty within the controller bandwidth in the form of parametric uncertainty

Recently developed quadratic stability and performance control techniques are used to design controllers for the active mass driver (AMD) benchmark problem. Several designs are obtained and analysed to highlight the utility of the proposed technique. Solution through the use of linear matrix inequal