Title :
A computationally efficient self-calibrating direction-of-arrival estimator
Author :
McArthur, Dean ; Reilly, James P.
Author_Institution :
Commun. Res. Lab., McMaster Univ., Hamilton, Ont., Canada
Abstract :
In this paper, we discuss new self-calibrating techniques for direction-of-arrival (DOA) estimation using an array of sensors, based on estimation-theoretic methods. We consider two cases; one where the background noise is known to be white; the other where the background noise is coloured with unknown covariance. Modern high-resolution array processing algorithms have long suffered from the sensitivity of the bearing estimates to sensor gain and phase calibration errors. This paper presents methods of jointly estimating both the incident DOA´s and calibration parameters, under the assumption that the radiation incident onto the array is in the form of a discrete number of plane waves. Simulation results are given which show that the performance of the proposed methods are significantly improved over conventional algorithms which do not take calibration errors into consideration
Keywords :
calibration; computational complexity; direction-of-arrival estimation; maximum likelihood estimation; white noise; CMAP; MLE; background noise; bearing estimates; calibration errors; coloured noise; computational efficiency; estimation-theoretic methods; high-resolution array processing algorithms; performance; phase calibration errors; plane waves; self-calibrating direction-of-arrival estimator; sensitivity; sensor array; sensor gain; simulation; unknown covariance; white noise; Array signal processing; Background noise; Calibration; Direction of arrival estimation; Maximum likelihood estimation; Phase estimation; Phased arrays; Sensor arrays; Signal processing algorithms; Uncertainty;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 1994. ICASSP-94., 1994 IEEE International Conference on
Conference_Location :
Adelaide, SA
Print_ISBN :
0-7803-1775-0
DOI :
10.1109/ICASSP.1994.389745
