Title :
Maximum likelihood angle-frequency parameter estimation in unknown noise fields for low-elevation target tracking
Author :
Djeddou, Mustapha ; Aouada, Said ; Zoubir, Abdelhak
Author_Institution :
Dept. of Electr. Eng., Ecole Nat. Polytech, Algiers, Algeria
Abstract :
In radar applications, the received echo signals reach the array elements via a multiplicity of paths even though there exist only one target. So, it is often relevant to estimate the direction and the Doppler frequency of each path ray. We apply in this paper a 2D extension of the approximate maximum likelihood (AML) algorithm to estimate these parameters using a sensor array in an unknown additive noise field. We consider the case where the complex fading factor fluctuates from one pulse repetition interval (PRI) to another one. Numerical simulations are provided to assess the performance of the approach, which is compared to the standard stochastic maximum likelihood derived for a white Gaussian noise.
Keywords :
array signal processing; direction-of-arrival estimation; echo; frequency estimation; maximum likelihood estimation; noise; radar signal processing; radar tracking; stochastic processes; target tracking; Doppler frequency; additive noise field; complex fading factor; low-elevation target tracking; maximum likelihood angle-frequency parameter estimation; path multiplicity; path ray; pulse repetition interval; radar applications; received echo signals; sensor array; stochastic maximum likelihood; unknown noise fields; Additive noise; Fading; Frequency estimation; Maximum likelihood estimation; Numerical simulation; Parameter estimation; Radar applications; Sensor arrays; Stochastic resonance; Target tracking;
Conference_Titel :
Signal Processing and Its Applications, 2003. Proceedings. Seventh International Symposium on
Print_ISBN :
0-7803-7946-2
DOI :
10.1109/ISSPA.2003.1224903
