Title :
Convergence properties of the multistage constant modulus array for correlated sources
Author :
Mathur, Amit ; Keerthi, Arvind V. ; Shynk, John J. ; Gooch, Richard P.
Author_Institution :
Dept. of Electr. & Comput. Eng., California Univ., Santa Barbara, CA, USA
fDate :
1/1/1997 12:00:00 AM
Abstract :
A steady-state analysis of the multistage constant modulus (CM) array is presented for the case of correlated source signals. Using a Wiener model for the converged adaptive algorithms, it is demonstrated that because of the cascade structure, signal cross-correlation causes “phantom” sources to be present. The resulting signal leakage in the adaptive cancellers between stages causes an increase in the minimum mean-square error. A parallel implementation that overcomes this loss in performance is described; it requires an initialization strategy to ensure that each stage captures a different source. Computer simulations are presented to illustrate the convergence properties of the cascade and parallel CM array systems and to verify the theoretical results
Keywords :
adaptive signal processing; array signal processing; cochannel interference; convergence of numerical methods; correlation methods; direction-of-arrival estimation; interference suppression; parallel processing; Wiener model; adaptive cancellers; cascade CM array systems; cascade structure; computer simulations; converged adaptive algorithms; convergence properties; correlated source signals; initialization strategy; minimum mean-square error; multistage constant modulus array; parallel implementation; phantom sources; signal crosscorrelation; signal leakage; steady-state analysis; Adaptive arrays; Antenna arrays; Computer simulation; Convergence; Covariance matrix; Performance loss; Signal analysis; Signal processing; Signal processing algorithms; Steady-state;
Journal_Title :
Signal Processing, IEEE Transactions on
