Title :
Optimum error quantization for LMS adaptation
Author :
Douglas, S.C. ; Meng, T.H.-Y.
Author_Institution :
Inf. Syst. Lab., Stanford Univ., CA, USA
Abstract :
The authors remove restrictions upon the transition and reconstruction levels of an L-level quantizer and examine error quantization as a design variable. The authors present a general performance factor expressing the misadjustment ratio of the quantized error algorithm with respect to the infinite-precision least-mean-squares (LMS) adaptation for a given convergence rate for Gaussian inputs. It is shown that maximizing this performance factor an an L-level quantizer with arbitrary transition levels and reconstruction levels produces the nonlinear system of equations defining the optimum Lloyd-Max quantizer for the Gaussian error. Simulations verify the theoretical performance loss predicted. The optimum-scaled uniform quantizer is shown to perform at most 0.013 dB worse than the optimum Lloyd-Max quantizer, indicating that in terms of both minimizing complexity and performance loss, uniform error quantization is close to the best for Gaussian inputs
Keywords :
adaptive filters; digital filters; filtering and prediction theory; least squares approximations; optimisation; Gaussian inputs; L-level quantizer; LMS adaptation; LMS adaptive filtering; arbitrary transition levels; convergence rate; design variable; digital filters; error quantization; general performance factor; infinite-precision least-mean-squares; optimum Lloyd-Max quantizer; optimum-scaled uniform quantizer; performance loss; quantized error algorithm; reconstruction levels; Adaptive filters; Adaptive systems; Additive noise; Algorithm design and analysis; Gaussian noise; Least squares approximation; Nonlinear equations; Quantization; Statistics; Transfer functions;
Conference_Titel :
Communications, Computers and Signal Processing, 1991., IEEE Pacific Rim Conference on
Conference_Location :
Victoria, BC
Print_ISBN :
0-87942-638-1
DOI :
10.1109/PACRIM.1991.160837
