Title :
Improving the threshold performance of higher-order direction finding methods via pseudorandomly generated estimator banks
Author :
Gershman, Alex B. ; Böhme, Johann F.
Author_Institution :
Dept. of Electr. Eng., Ruhr-Univ., Bochum, Germany
Abstract :
A recently reported estimator bank approach (see IEEE SP Lett., vol.4, p.54, 1997) is extended below to the fourth-order direction finding algorithms. The essence of our approach is to exploit “parallel” underlying eigenstructure based estimators for removing the outliers and improving the direction finding performance in the threshold domain. The pseudorandomly generated weighted fourth-order MUSIC estimators are exploited as underlying techniques for estimator bank. Motivated by the superior performance and reduced computational complexity of beamspace and root modifications of the second-order eigenstructure techniques, beamspace root implementations of fourth-order MUSIC and fourth-order estimator bank are developed. Simulations show dramatical improvements of the threshold performance
Keywords :
computational complexity; covariance analysis; direction-of-arrival estimation; eigenstructure assignment; random processes; DOA estimation; beamspace; computational complexity; direction finding performance; eigenstructure based estimators; fourth-order direction finding algorithms; higher-order direction finding methods; outliers; pseudorandomly generated estimator banks; root modifications; second-order eigenstructure techniques; simulations; threshold domain; threshold performance; weighted fourth-order MUSIC estimators; Computational complexity; Computational modeling; Degradation; Direction of arrival estimation; Gaussian noise; Multiple signal classification; Sensor arrays; Signal generators; Signal to noise ratio; Silicon carbide;
Conference_Titel :
Higher-Order Statistics, 1997., Proceedings of the IEEE Signal Processing Workshop on
Conference_Location :
Banff, Alta.
Print_ISBN :
0-8186-8005-9
DOI :
10.1109/HOST.1997.613532
