DocumentCode
1465089
Title
Hybrid FM-polynomial phase signal modeling: parameter estimation and Cramer-Rao bounds
Author
Gini, Fulvio ; Giannakis, Georgios B.
Author_Institution
Dept. Ingegneria dell´´Inf., Pisa Univ., Italy
Volume
47
Issue
2
fYear
1999
fDate
2/1/1999 12:00:00 AM
Firstpage
363
Lastpage
377
Abstract
Parameter estimation for a class of nonstationary signal models is addressed. The class contains combination of a polynomial-phase signal (PPS) and a frequency-modulated (FM) component of the sinusoidal or hyperbolic type. Such signals appear in radar and sonar applications involving moving targets with vibrating or rotating components. A novel approach is proposed that allows us to decouple estimation of the FM parameters from those of the PPS, relying on properties of the multilag high-order ambiguity function (ml-HAF). The accuracy achievable by any unbiased estimator of the hybrid FM-PPS parameters is investigated by means of the Cramer-Rao lower bounds (CRLBs). Both exact and large sample approximate expressions of the bounds are derived and compared with the performance of the proposed methods based on Monte Carlo simulations
Keywords
FM radar; approximation theory; parameter estimation; radar signal processing; signal sampling; sonar signal processing; Cramer-Rao lower bounds; FM parameters; Monte Carlo simulations; exact expressions; frequency-modulated component; hybrid FM-polynomial phase signal modeling; hyperbolic signal; large sample approximate expressions; multilag high-order ambiguity function; nonstationary signal models; parameter estimation; performance; polynomial-phase signal; radar applications; rotating components; sinusoidal signal; sonar applications; target classification; unbiased estimator; vibrating components; Additive noise; Chirp; Doppler radar; Frequency modulation; Health information management; Parameter estimation; Polynomials; Power harmonic filters; Radar applications; Sonar applications;
fLanguage
English
Journal_Title
Signal Processing, IEEE Transactions on
Publisher
ieee
ISSN
1053-587X
Type
jour
DOI
10.1109/78.740122
Filename
740122
Link To Document