Title :
Absolute stability and dissipativity of continuous time multilayer recurrent neural networks
Author :
Suykens, J.A.K. ; Vandewalle, J.
Author_Institution :
ESAT, Katholieke Univ., Leuven, Heverlee, Belgium
Abstract :
In this paper we present a sufficient condition for global asymptotic stability of continuous time multilayer recurrent neural networks with two-hidden layers. The condition is based on a Lur´e-Postnikov Lyapunov function and is expressed as a matrix inequality. With respect to input/output stability a condition for dissipativity is derived, which includes, for example, the cases of passivity and finite L2-gain. This result is based on a quadratic storage function plus integral term. For nonlinear modelling and control purposes it enables to modify the classical dynamical backpropagation algorithm with a matrix inequality constraint in order to guarantee stable identified models or stable closed-loop control schemes, in a similar fashion has this can be done in discrete time NL q theory
Keywords :
Lyapunov matrix equations; absolute stability; asymptotic stability; continuous time systems; recurrent neural nets; Lur´e-Postnikov Lyapunov function; NLq theory; absolute stability; closed-loop control; continuous time multilayer recurrent neural network; dissipativity; dynamical backpropagation algorithm; finite L2-gain; global asymptotic stability; input/output stability; matrix inequality; model identification; nonlinear control; nonlinear model; passivity; quadratic storage function; two-hidden layers; Asymptotic stability; Backpropagation algorithms; Control theory; Linear matrix inequalities; Lyapunov method; Multi-layer neural network; Neural networks; Recurrent neural networks; Stability criteria; Sufficient conditions;
Conference_Titel :
Circuits and Systems, 1997. ISCAS '97., Proceedings of 1997 IEEE International Symposium on
Print_ISBN :
0-7803-3583-X
DOI :
10.1109/ISCAS.1997.608791
