A RANDOM MATRIX THEORY MODEL FOR THE DOMINANT MODE REJECTION BEAMFORMER NOTCH DEPTH

John R. Buck; Kathleen E. Wage

doi:10.1109/SSP.2012.6319832

A RANDOM MATRIX THEORY MODEL FOR THE DOMINANT MODE REJECTION BEAMFORMER NOTCH DEPTH

John R. Buck Kathleen E. Wage

2012 IEEE Statistical Signal Processing Workshop, pp.820-823

01/01/2012

: https://doi.org/10.1109/SSP.2012.6319832

Engineering, Electrical & Electronic

Science & Technology

Engineering

Technology

The Dominant Mode Rejection (DMR) adaptive beamformer (ABF) computes its array weights by substituting a modified sample covariance matrix into the expression for the Capon beamformer array weights. Incorporating recent random matrix theory results on sample eigenvector fidelity for spiked covariance models into the DMR beampattern expression results in a model for the notch depth in the direction of a single loud interferer. The model predicts the mean DMR notch depth as a function of the number of snapshots, the interferer-to-noise ratio (INR), the array size, and the interferer location relative to the look direction. The model predictions agree closely with simulations over a wide range of INRs and snapshots.

: A RANDOM MATRIX THEORY MODEL FOR THE DOMINANT MODE REJECTION BEAMFORMER NOTCH DEPTH
: John R. Buck - University of Massachusetts Dartmouth
Kathleen E. Wage - George Mason University
: 2012 IEEE Statistical Signal Processing Workshop, pp.820-823
: IEEE
: 4
: English
: N00014-09-1-167; N00014-12-1-0047; N00014-09-1-0114; N00014-09-1-0675; N00014-12-1-0048 / ONR Awards
: Department of Electrical and Computer Engineering
: Conference proceeding
: 9781467301824; 1467301825; 9781467301831; 1467301833; 9781467301831; 1467301833
: 9914419619701301