Multisource Self-Calibration for Sensor Arrays

Multisource Self-Calibration for Sensor Arrays

Calibration of a sensor array is more involved if the antennas have direction dependent gains and multiple calibrator sources are simultaneously present. We study this case for a sensor array with arbitrary geometry but identical elements, i.e., elements with the same direction dependent gain patter...

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Veröffentlicht in:IEEE transactions on signal processing 2009-09, Vol.57 (9), p.3512-3522
Hauptverfasser: Wijnholds, S.J., van der Veen, A.-J.
Format: Artikel
Sprache:eng
Schlagworte:
Antenna arrays
Antennas and propagation
Applied sciences
Array signal processing
Arrays
Asymptotic properties
Calibration
Computer simulation
Delay effects
Detection, estimation, filtering, equalization, prediction
Directive antennas
Exact sciences and technology
Gain
Information, signal and communications theory
Ionosphere
Least squares method
Miscellaneous
Monte Carlo methods
Phased arrays
Radio astronomy
self-calibration
Sensor arrays
Signal and communications theory
Signal processing
Signal, noise
Telecommunications and information theory
Telescopes
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Zusammenfassung:Calibration of a sensor array is more involved if the antennas have direction dependent gains and multiple calibrator sources are simultaneously present. We study this case for a sensor array with arbitrary geometry but identical elements, i.e., elements with the same direction dependent gain pattern. A weighted alternating least squares (WALS) algorithm is derived that iteratively solves for the direction independent complex gains of the array elements, their noise powers and their gains in the direction of the calibrator sources. An extension of the problem is the case where the apparent calibrator source locations are unknown, e.g., due to refractive propagation paths. For this case, the WALS method is supplemented with weighted subspace fitting (WSF) direction finding techniques. Using Monte Carlo simulations we demonstrate that both methods are asymptotically statistically efficient and converge within two iterations even in cases of low SNR.
ISSN:1053-587X
1941-0476
DOI:10.1109/TSP.2009.2022894