Title :
Identification of MIMO Hammerstein-Wiener system
Author :
Jing Bai ; Zhizhong Mao ; Feng Yu ; Yajun Wang
Author_Institution :
Coll. of Inf. Sci. & Eng., Northeastern Univ., Shenyang, China
fDate :
May 31 2014-June 2 2014
Abstract :
A new approach to identification of multi-input multi-output (MIMO) Hammerstein-Wiener system is presented. The output nonlinear block consists of several single-input single-output (SISO) blocks, one of which is dead zone and saturation nonlinearity. The hinging hyperplane (HH) model expresses the character. The MIMO input nonlinear block is described by multi layer feed forward neural networks. The transfer function matrix indicates the MIMO linear dynamics block. According to the prior structure knowledge, the identification problem is transformed to constrained optimization using prediction error method (PEM). The interior-point method (IPM) is adopted to solve the nonlinear programming. Finally, the simulation examples illustrate the performance and validate the effectiveness of the proposed algorithm.
Keywords :
MIMO systems; control nonlinearities; feedforward neural nets; neurocontrollers; nonlinear control systems; nonlinear programming; transfer function matrices; HH model; IPM; MIMO Hammerstein-Wiener system; MIMO linear dynamics block; PEM; SISO blocks; constrained optimization; dead zone; hinging hyperplane model; interior-point method; multi-input multi-output system; multilayer feedforward neural networks; nonlinear programming; output nonlinear block; prediction error method; saturation nonlinearity; single-input single-output block; system identification; transfer function matrix; Educational institutions; MIMO; Mathematical model; Optimization; Prediction algorithms; Predictive models; Vectors; Hammerstein-Wiener; Hinging hyperplane; IPM and PEM; Neural networks;
Conference_Titel :
Control and Decision Conference (2014 CCDC), The 26th Chinese
Conference_Location :
Changsha
Print_ISBN :
978-1-4799-3707-3
DOI :
10.1109/CCDC.2014.6852346
