Title :
EM-based recursive estimation of channel parameters
Author :
Zamiri-Jafarian, Hossein ; Pasupathy, Subbarayan
Author_Institution :
Dept. of Electr. & Comput. Eng., Toronto Univ., Ont., Canada
fDate :
9/1/1999 12:00:00 AM
Abstract :
Recursive (online) expectation-maximization (EM) algorithm along with stochastic approximation is employed in this paper to estimate unknown time-invariant/variant parameters. The impulse response of a linear system (channel) is modeled as an unknown deterministic vector/process and as a Gaussian vector/process with unknown stochastic characteristics. Using these models which are embedded in white or colored Gaussian noise, different types of recursive least squares (RLS), Kalman filtering and smoothing and combined RLS and Kalman-type algorithms are derived directly from the recursive EM algorithm. The estimation of unknown parameters also generates new recursive algorithms for situations, such as additive colored noise modeled by an autoregressive process. The recursive EM algorithm is shown as a powerful tool which unifies the derivations of many adaptive estimation methods
Keywords :
Gaussian noise; Kalman filters; adaptive estimation; autoregressive processes; filtering theory; least squares approximations; maximum likelihood estimation; optimisation; recursive estimation; telecommunication channels; transient response; EM-based recursive estimation; Gaussian vector/process; Kalman filtering; Kalman-type algorithm; MLE; RLS algorithm; adaptive estimation methods; additive colored noise; autoregressive process; channel estimation; channel parameters; colored Gaussian noise; deterministic vector/process; impulse response; linear system; online expectation-maximization algorithm; recursive least squares; smoothing; stochastic approximation; stochastic characteristics; time-invariant/variant parameters; white Gaussian noise; Approximation algorithms; Filtering algorithms; Least squares approximation; Linear systems; Recursive estimation; Resonance light scattering; Stochastic processes; Stochastic resonance; Stochastic systems; Vectors;
Journal_Title :
Communications, IEEE Transactions on
