Title :
Predicting the array gain of partially coherent planar HF arrays
Author :
Harms, Andrew ; Hickman, Granger ; Papazoglou, Michael ; Krolik, Jeffrey
Author_Institution :
STRAD Corp., Chapel Hill, NC, USA
Abstract :
This paper concerns estimating the partially coherent signal gain of a large, fully-populated planar HF phasedarray using simulated data from a few widely distributed receive elements. Our approach involves estimating magnitude-squared coherence between sensor elements in order to estimate parameters of a 2-D exponential model for signal decoherence, which, in turn, is used to predict array gain. Via cross-validation, this approach is shown to correctly predict the array gain observed in simulated data using well-established models for ionospheric perturbations. Finally, it is used to predict the signal gains achievable for large fully-populated planar HF arrays.
Keywords :
array signal processing; estimation theory; parameter estimation; 2D exponential model; distributed receive element; fully-populated planar HF phased-array; ionospheric perturbation; magnitude-squared coherence estimation; parameter estimation; partially coherent array signal gain estimation; partially coherent planar HF array; sensor element; signal decoherence; Approximation methods; Arrays; Coherence; Gain; Hafnium; Manganese; Signal to noise ratio;
Conference_Titel :
Radar Conference, 2014 IEEE
Conference_Location :
Cincinnati, OH
Print_ISBN :
978-1-4799-2034-1
DOI :
10.1109/RADAR.2014.6875830
