Title :
Linear multichannel blind equalizers of nonlinear FIR Volterra channels
Author :
Giannakis, Georgios B. ; Serpedin, Erchin
Author_Institution :
Dept. of Electr. Eng., Virginia Univ., Charlottesville, VA, USA
fDate :
1/1/1997 12:00:00 AM
Abstract :
Truncated Volterra expansions model nonlinear systems encountered with satellite communications, magnetic recording channels, and physiological processes. A general approach for blind deconvolution of single-input multiple-output Volterra finite impulse response (FIR) systems is presented. It is shown that such nonlinear systems can be blindly equalized using only linear FIR filters. The approach requires that the Volterra kernels satisfy a certain coprimeness condition and that the input possesses a minimal persistence-of-excitation order. No other special conditions are imposed on the kernel transfer functions or on the input signal, which may be deterministic or random with unknown statistics. The proposed algorithms are corroborated with simulation examples
Keywords :
FIR filters; Volterra series; deconvolution; equalisers; filtering theory; linear systems; magnetic recording; matrix algebra; nonlinear systems; parameter estimation; telecommunication channels; transfer functions; Volterra finite impulse response systems; Volterra kernels; algorithms; blind deconvolution; coprimeness condition; deterministic signal; input possesses; input signal; kernel transfer functions; linear FIR filters; linear multichannel blind equalizers; magnetic recording channels; minimal persistence of excitation order; nonlinear FIR Volterra channels; nonlinear systems; physiological processes; random signal; satellite communications; signal statistics; simulation; single-input multiple-output; truncated Volterra expansions; Blind equalizers; Deconvolution; Downlink; Finite impulse response filter; Kernel; Magnetic recording; Nonlinear filters; Nonlinear systems; Polynomials; Satellite communication;
Journal_Title :
Signal Processing, IEEE Transactions on
