Title :
Neural approximations for receding-horizon controllers
Author :
Cattaneo, A. ; Parisini, T. ; Raiteri, R. ; Zoppoli, R.
Author_Institution :
Dept. of Comput. Sci., Genoa Univ., Italy
fDate :
29 June-1 July 1994
Abstract :
A receding-horizon (RH) optimal control scheme for a discrete-time nonlinear dynamic system is presented. A nonquadratic cost function is considered and constraints are imposed on both the state and control vectors. Two main results are reported. The first consists in deriving a stabilizing regulator without imposing, as is usually required by existing RH control schemes, that either the origin (i.e. the equilibrium point of the dynamic system) or a suitable neighbourhood of the origin be reached within a finite time. Stability is achieved by adding a proper terminal penalty function to the process cost. The second result consists in generating the control vector by means of a feedback control law computed off line instead of computing it on line, as is done for existing RH regulators. The off-line computation is performed by approximating the RH regulator by means of a multilayer feedforward neural network.
Keywords :
approximation theory; discrete time systems; feedback; feedforward neural nets; neurocontrollers; nonlinear dynamical systems; optimal control; stability; control vector; discrete-time nonlinear dynamic system; feedback control; feedforward neural network; neural approximations; nonquadratic cost function; receding-horizon controllers; stability; stabilizing regulator; state vectors; terminal penalty function; Computer networks; Control systems; Cost function; Feedback control; Multi-layer neural network; Neural networks; Nonlinear dynamical systems; Optimal control; Regulators; Stability;
Conference_Titel :
American Control Conference, 1994
Print_ISBN :
0-7803-1783-1
DOI :
10.1109/ACC.1994.752455
