Title :
Estimating time-varying DOA and Doppler shift in radar array processing
Author :
Vincent, F. ; Besson, O.
Author_Institution :
Dept. of Avionics & Syst., ENSICA, Toulouse, France
fDate :
12/1/2000 12:00:00 AM
Abstract :
The authors consider the problem of retrieving information about space debris in low-Earth orbit by means of a radar system operating in a bi-static mode. More exactly, a pulse radar steers a beam in a prescribed region of space. When crossing the main lobe of the radar, a moving object will reflect energy towards a ground-based array of sensors. The signal is affected by Doppler shift, which is related to the radial speed. Additionally, its direction-of-arrival (DOA), related to the orthoradial speed, will be time-varying. Maximum likelihood (ML) solutions to the problem of estimating both the Doppler shift and the time-varying DOA are proposed. Since the exact ML solution is computationally intensive, a simpler alternative is presented that relies on the extended invariance principle. The new method is shown to be simple as it only entails Fourier transforms and linear computations. Its performance is illustrated via numerical simulations
Keywords :
Doppler radar; Doppler shift; array signal processing; direction-of-arrival estimation; fast Fourier transforms; maximum likelihood estimation; radar antennas; radar signal processing; Doppler shift estimation; FFT; asymptotically statistically efficient method; beam steering; bi-static mode; complex exponential signal; direction-of-arrival; extended invariance principle; fast Fourier transforms; ground-based sensor array; high SNR; linear computations; low-Earth orbit; main lobe; maximum likelihood solutions; numerical simulations; orthoradial speed; performance; pulse radar; radar array processing; radar system; radial speed; space debris; time-varying DOA estimation;
Journal_Title :
Radar, Sonar and Navigation, IEE Proceedings -
DOI :
10.1049/ip-rsn:20000727
