Title :
An adaptive technique for modeling second-order Volterra systems with sparse kernels
Author :
Tan, Li ; Jiang, Jean
Author_Institution :
Dept. of Electron., DeVry Inst. of Technol., Decater, GA, USA
fDate :
12/1/1998 12:00:00 AM
Abstract :
This paper proposes a simple technique for modeling second-order Volterra systems using an adaptive second-order Volterra delay filter (ASOVDF). The developed filter structure essentially extends an adaptive FIR delay filter to include linear and quadratic filter coefficients with an input assumed to be a zero-mean i.i.d. sequence with a symmetric distribution. The implementation of the ASOVDF is based on a stage-by-stage modeling process. At each stage, a dominant delay element is determined, the corresponding adaptive filter coefficient is incorporated to the adaptive filter coefficients from previous stages, and then these filter coefficients are adapted via the recursive least-squares algorithm. The ASOVDF requires few filter coefficients and has better performance and less computational complexity over the conventional adaptive second-order Volterra filter (ASOVF) in modeling second-order Volterra systems with sparse kernels
Keywords :
Volterra series; adaptive filters; computational complexity; delay filters; least squares approximations; sparse matrices; Volterra delay filter; adaptive technique; computational complexity; dominant delay element; linear filter coefficients; quadratic filter coefficients; recursive least-squares algorithm; second-order Volterra systems; sparse kernels; zero-mean i.i.d. sequence; Adaptive filters; Adaptive systems; Computational complexity; Delay effects; Delay estimation; Finite impulse response filter; IIR filters; Kernel; Nonlinear filters; Signal processing algorithms;
Journal_Title :
Circuits and Systems II: Analog and Digital Signal Processing, IEEE Transactions on
