Title :
Neural network-based control design: an LMI approach
Author :
Limanond, Suttipan ; Si, Jennie
Author_Institution :
Dept. of Electr. Eng., Arizona State Univ., Tempe, AZ, USA
fDate :
11/1/1998 12:00:00 AM
Abstract :
We address a neural network-based control design for a discrete-time nonlinear system. Our design approach is to approximate the nonlinear system with a multilayer perceptron of which the activation functions are of the sigmoid type symmetric to the origin. A linear difference inclusion representation is then established for this class of approximating neural networks and is used to design a state feedback control law for the nonlinear system based on the certainty equivalence principle. The control design equations are shown to be a set of linear matrix inequalities where a convex optimization algorithm can be applied to determine the control signal. Further, the stability of the closed-loop is guaranteed in the sense that there exists a unique global attraction region in the neighborhood of the origin to which every trajectory of the closed-loop system converges. Finally, a simple example is presented so as to illustrate our control design procedure
Keywords :
closed loop systems; discrete time systems; matrix algebra; multilayer perceptrons; neurocontrollers; nonlinear control systems; state feedback; transfer functions; LMI approach; activation functions; approximating neural networks; certainty equivalence principle; convex optimization algorithm; discrete-time nonlinear system; linear difference inclusion; linear matrix inequalities; multilayer perceptron; neural network-based control design; sigmoid type symmetric functions; unique global attraction region; Control design; Control systems; Linear feedback control systems; Linear matrix inequalities; Multilayer perceptrons; Neural networks; Nonlinear control systems; Nonlinear equations; Nonlinear systems; State feedback;
Journal_Title :
Neural Networks, IEEE Transactions on
