Title :
Adaptive nonlinear control of agile antiair missiles using neural networks
Author :
McFarland, Michael B. ; Calise, Anthony J.
Author_Institution :
Raytheon Missile Syst. Co., Tucson, AZ, USA
fDate :
9/1/2000 12:00:00 AM
Abstract :
Research has shown that neural networks can be used to improve upon approximate dynamic inversion controllers in the case of uncertain nonlinear systems. In one possible architecture, the neural network adaptively cancels linearization errors through online learning. Learning may be accomplished by a simple weight update rule derived from Lyapunov theory, thus assuring the stability of the closed-loop system. In the paper, the authors discuss the evolution of this methodology and its application in a bank-to-turn autopilot design for an agile antiair missile. First, a control scheme based on approximate inversion of the vehicle dynamics is presented. This nonlinear control system is then augmented by the addition of a feedforward neural network with online learning. Finally, the resulting control law is demonstrated in a nonlinear simulation and its performance is evaluated relative to a conventional gain-scheduled linear autopilot
Keywords :
Adaptive control; Closed loop systems; Control system synthesis; Feedforward neural nets; Learning systems; Lyapunov methods; Missile control; Neurocontrollers; Nonlinear control systems; Robust control; Uncertain systems; Lyapunov theory; adaptive nonlinear control; agile antiair missiles; approximate dynamic inversion controller; bank-to-turn autopilot; conventional gain-scheduled linear autopilot; linearization errors; nonlinear simulation; online learning; uncertain nonlinear systems; weight update rule; Adaptive control; Control systems; Missiles; Neural networks; Nonlinear control systems; Nonlinear dynamical systems; Nonlinear systems; Programmable control; Stability; Vehicle dynamics;
Journal_Title :
Control Systems Technology, IEEE Transactions on
