Title :
Blind identification of LTI-ZMNL-LTI nonlinear channel models
Author :
Prakriya, Shankar ; Hatzinakos, Dimitrios
Author_Institution :
Dept. of Electr. & Comput. Eng., Toronto Univ., Ont., Canada
fDate :
12/1/1995 12:00:00 AM
Abstract :
A simple method is proposed for blind identification of discrete-time nonlinear models consisting of two linear time invariant (LTI) subsystems separated by a polynomial-type zero memory nonlinearity (ZMNL) of order N (the LTI-ZMNL-LTI model). The linear subsystems are allowed to be of nonminimum phase (NMP), though the first LTI can be completely identified only if it is of minimum phase. With a circularly symmetric Gaussian input, the linear subsystems can be identified using simple cepstral operations on a single 2-D slice of the N+1 th-order polyspectrum of the output signal. The linear subsystem of an LTI-ZMNL model can be identified using only a 1-D moment or polyspectral slice if it is of minimum phase. The ZMNL coefficients are not identified and need not be known. The order N of the nonlinearity can, in principle, be estimated from the output signal. The methods are analytically simple, computationally efficient, and possess noise suppression characteristics. Computer simulations are presented to support the theory
Keywords :
Gaussian channels; cepstral analysis; discrete time systems; identification; linear systems; LTI-ZMNL-LTI nonlinear channel models; blind identification; cepstral operations; circularly symmetric Gaussian input; discrete-time nonlinear models; linear subsystems; linear time invariant subsystems; minimum phase; moment; noise suppression; nonminimum phase; polynomial-type zero memory nonlinearity; polyspectral; Application software; Cepstral analysis; Computer simulation; Kernel; Magnetic recording; Microwave communication; Nonlinear systems; Polynomials; Signal processing; Transfer functions;
Journal_Title :
Signal Processing, IEEE Transactions on
