Application of ensemble training of a structural controller to the AMD benchmark problem

In this paper, we investigate the performance of optimal polynomial control for the vibration suppression of a benchmark problem; namely, the active tendon system. The optimal polynomial controller is a summation of polynomials of different orders, i.e., linear, cubic, quintic, etc., and the gain ma

In this paper, both the methods of continuous sliding mode control (CSMC) and continuous sliding mode control with compensators (CSMC&C) have been applied to two benchmark structures, namely, a building model equipped with an active mass driver system, and a building model equipped with an active te

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

Methodology for active structural control using neural networks has been proposed by Ghaboussi and his co-workers [1][2][3][4][5][6][7][8] in the past several years. The control algorithm in the mathematically formulated methods is replaced by a neural network controller (neuro-controller). Neuro-co

A non-linear robust output feedback control is designed for a sixth-order model of an induction motor. The control uses only measurement of the rotor position and stator currents. It contains two observers, a second-order observer to estimate the rotor #ux from the stator current and a third-order h

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