Title :
Adaptive Lattice-Hammerstein RLS algorithm for wireless nonlinear equalizers
Author :
Eghtedari, M. ; Kahaei, M.H. ; Poshtan, J.
Author_Institution :
Coll. of Electr. Eng., Iran Univ. of Sci. & Technol., Tehran, Iran
Abstract :
In this paper, the adaptive Recursive Least-Squares algorithm is derived for the Lattice-Hammerstein filter leading to the proposed RLS Lattice-Hammerstein nonlinear adaptive filter. The performance of the proposed algorithm is compared to both SG Lattice-Hammerstein and LMS Transversal-Hammerstein algorithms in a nonlinear channel modeling scenario. It is shown that the convergence rate of the RLS Lattice-Hammerstein algorithm is much higher than the other two with a lower steady-state error. Simplicity of the Hammerstein structure compared to the Volterra expression makes is more appropriate for modeling and equalizing nonlinear channels.
Keywords :
adaptive filters; equalisers; lattice filters; nonlinear filters; recursive filters; Hammerstein series; LMS Transversal-Hammerstein algorithm; Lattice structure; Lattice-Hammerstein filter; RLS Lattice-Hammerstein nonlinear adaptive filter; SG Lattice-Hammerstein algorithm; Volterra series; adaptive Lattice-Hammerstein RLS algorithm; adaptive Recursive Least-Squares algorithm; nonlinear channel equalization; nonlinear channel modeling; steady-state error; wireless nonlinear equalizers; Adaptive filters; Convergence; Educational institutions; Equalizers; Lattices; Least squares approximation; Least squares methods; Polynomials; Resonance light scattering; Steady-state; Hammerstein series; Lattice structure; RLS Algorithm; Volterra series;
Conference_Titel :
Internet, 2005.The First IEEE and IFIP International Conference in Central Asia on
Print_ISBN :
0-7803-9179-9
DOI :
10.1109/CANET.2005.1598182
