Abstract
The distribution of the received signals in many array processing applications is noncircular. Although optimal widely linear beamformer (WLB) can provide the best performance for noncircular received signals, its performance degrades severely under model mismatches in practical applications. As a remedy, we propose a robust WLB by using precise reconstruction of extended interference-plus-noise covariance matrix (EINCM) and low-complexity estimation of extended desired signal steering vector (EDSSV). We propose to first determine the steering vectors, powers, and noncircularity coefficients of all signals and the noise power. In contrast to the previous reconstruction methods using the integration over a wide angular sector, we reconstruct the interference-plus-noise covariance matrix (INCM) and the pseudo INCM accurately according to their definitions. By using INCM and pseudo INCM, we can precisely reconstruct the EINCM. We propose to estimate the EDSSV by intersecting two extended subspaces, which are respectively formed by eigendecomposing the extended sample covariance matrix and the extended desired signal covariance matrix. Unlike the convex optimization methods, the proposed EDSSV estimation does not require any optimization programming and yields a solution with closed expression in low computational complexity. Simulation results show that the proposed robust WLB provides near optimal performance under several model mismatch cases.
Highlights
Adaptive beamforming aims at extracting desired signal (DS) while suppressing interferences and noise and is a fundamental technique in array signal processing [1,2,3,4,5]
We propose to reconstruct the interference-plus-noise covariance matrix (INCM) and the pseudo INCM accurately according to their definitions instead of the integration over interference-plus-noise angular sector
In the proposed widely linear beamformer (WLB), the main computational cost of extended interference-plus-noise covariance matrix (EINCM) reconstruction lies in the eigendecomposition of Rxwith a complexity of O(N3), and the extended desired signal steering vector (EDSSV) estimation has a complexity of O(8N3) dominated by the eigendecomposition of Rxfrom the standpoint of computational complexity
Summary
By stacking x(k) and its conjugate component, we define the extended observation vector as x(k) = x(k)T , x(k)H T. where b1 = aT1 , 0TN T , c1 = 0TN , aH1 T , and v(k) = v(k)T , v(k)H T. Where a1 is the noncircular EDSSV and vγ (k) is the global noise vector for x(k). The WLB output is denoted as y(k) = w H x(k) = s1(k)w H a1 + w H vγ (k),. The output signal-to-interference-plus-noise ratio (SINR) of a WLB is defined as σ12|w H a1|2 w H Rvγ w (16). The theoretical Rvγ and a1 are not available in practice In such cases, one may approximate Rvγ as the following extended SCM. The unknown vector a1 is usually approximated by the presumed EDSSV a ̆1 with the exactly known DS noncircularity coefficient γ1.
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