Title :
All-Pole Estimation in Spectral Domain
Author_Institution :
Austrian Acad. of Sci., Vienna
Abstract :
Autoregressive (AR) modeling is a popular spectral analysis method commonly resolved in the time domain. This paper presents a novel AR analysis framework dealing with the estimation of poles directly from spectral samples. The basis of the method lies on a minimizing functional built with a certain mapping of the spectral residue. The optimization mechanism is based on the multivariate Newton-Raphson algorithm. Two different mappings are considered, namely, linear and logarithmic. The linear case results in a nonquadratic convex functional, whose global minimum is equivalent to that of the time-domain autocorrelation method. The logarithmic case under the maximum likelihood criterion turns out equivalent to the Whittle likelihood, proven here to be suitable for frequency selective estimation. The statistical and convergence performance of the method is demonstrated with simulations on stochastic and deterministic harmonic signals.
Keywords :
Newton-Raphson method; autoregressive processes; maximum likelihood estimation; spectral analysis; time-domain analysis; autoregressive modeling; deterministic harmonic signals; frequency selective estimation; maximum likelihood criterion; multivariate Newton-Raphson algorithm; nonquadratic convex functional; optimization mechanism; pole estimation; spectral analysis method; spectral domain; spectral residue; time-domain autocorrelation method; Autocorrelation; Convergence; Frequency domain analysis; Frequency estimation; Maximum likelihood estimation; Quantization; Robust stability; Spectral analysis; Stochastic processes; Time domain analysis; Autoregressive (AR) model; frequency domain; maximum-likelihood estimation; pole update;
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2007.897880
