Title :
Decorrelation algorithm for blind decision feedback equalizer with lattice structures
Author :
Bateman, Andrew J. ; Bar-Ness, Yeheskel ; Kamel, Raafat E.
Author_Institution :
Dept. of Electr. & Comput. Eng., New Jersey Inst. of Technol., Newark, NJ, USA
Abstract :
A new algorithm was previously introduced for blind, adaptive equalization, known as the decorrelation algorithm. The algorithm is based on decorrelating the input to the decision or threshold device of a decision feedback equalizer to reduce the intersymbol interference at the equalizer´s output. To increase the rate of convergence of this blind, adaptive, decision feedback equalizer, a fast Kalman structure was proposed, but not without a dramatic increase in complexity and limited numerical stability. In the present paper, more computationally efficient lattice-based structures are proposed. Using the decorrelation algorithm to control these structures, the authors maintain a high rate of convergence with better numerical stability in finite-precision environments
Keywords :
Kalman filters; computational complexity; decision feedback equalisers; interference suppression; intersymbol interference; lattice filters; least squares approximations; numerical stability; recursive filters; blind decision feedback equalizer; complexity; convergence; decorrelation algorithm; fast Kalman structure; finite-precision environments; intersymbol interference; lattice structures; lattice-based structures; numerical stability; Blind equalizers; Convergence of numerical methods; Decision feedback equalizers; Decorrelation; Intersymbol interference; Kalman filters; Lattices; Numerical stability; Resonance light scattering; Signal processing algorithms;
Conference_Titel :
Digital Signal Processing Workshop, 1994., 1994 Sixth IEEE
Conference_Location :
Yosemite National Park, CA
Print_ISBN :
0-7803-1948-6
DOI :
10.1109/DSP.1994.379829
