Title :
The error variance of the optimal linear smoother and maximum-variance fractional pole models
Author :
Georgiou, Tryphon T.
Author_Institution :
IEEE Fellow
Abstract :
The variance of the optimal one-step ahead linear prediction error of a discrete-time stationary stochastic process is given by the well-known Szego-Kolmogorov formula as the geometric mean of the spectral density function. We first derive an analogous expression for the optimal linear smoother which uses the infinite past and the infinite future to determine the present. The least variance turns out to be the harmonic mean of the spectral density function. Building on this, we explore the question of what is the most random power spectrum in the sense of corresponding to the largest variance optimal linear smoother (i.e., least "smoothable"), which is consistent with finitely many covariance moments. It turns out that it can be described by an all-pole model, albeit the poles are fractional
Keywords :
discrete time systems; optimal systems; poles and zeros; smoothing methods; stochastic processes; Szego-Kolmogorov formula; discrete-time stationary stochastic process; error variance; linear prediction error; maximum-variance fractional pole model; optimal linear smoother; spectral density function; Density functional theory; Error correction; Optimal control; Power harmonic filters; Power measurement; Predictive models; Random processes; Smoothing methods; Solid modeling; USA Councils;
Conference_Titel :
Decision and Control, 2006 45th IEEE Conference on
Conference_Location :
San Diego, CA
Print_ISBN :
1-4244-0171-2
DOI :
10.1109/CDC.2006.377324
