Robust adaptive beamformers based on worst-case optimization and constraints on magnitude response
IEEE Transactions on Signal Processing
Robust beamforming in cognitive radio
IEEE Transactions on Wireless Communications
The Linearly Constrained LSCMA for Blind Multi-user Detection
Wireless Personal Communications: An International Journal
Robust adaptive beamforming in partly calibrated sparse sensor arrays
IEEE Transactions on Signal Processing
Robust Adaptive Beamforming Under Quadratic Constraint with Recursive Method Implementation
Wireless Personal Communications: An International Journal
Robust presteering derivative constraints for broadband antennaarrays
IEEE Transactions on Signal Processing
Minimum variance beamforming with soft response constraints
IEEE Transactions on Signal Processing
A Bayesian approach to robust adaptive beamforming
IEEE Transactions on Signal Processing
A projection approach for robust adaptive beamforming
IEEE Transactions on Signal Processing
Doubly constrained robust Capon beamformer
IEEE Transactions on Signal Processing
IEEE Transactions on Signal Processing
Iterative Robust Minimum Variance Beamforming
IEEE Transactions on Signal Processing
Clustered Blind Beamforming From Ad-Hoc Microphone Arrays
IEEE Transactions on Audio, Speech, and Language Processing
IEEE Transactions on Wireless Communications
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The linearly constrained least squares constant modulus algorithm (LSCMA) may suffer significant performance degradation and lack robustness in the presence of the slight mismatches between the actual and assumed signal steering vectors, which can cause the serious problem of desired signal cancellation. To account for the mismatches, we propose a doubly constrained robust LSCMA based on explicit modeling of uncertainty in the desired signal array response and data covariance matrix, which provides robustness against pointing errors and random perturbations in detector parameters. Our algorithm optimizes the worst-case performance by minimizing the output SINR while maintaining a distortionless response for the worst-case signal steering vector. The weight vector can be optimized by the partial Taylor-series expansion and Lagrange multiplier method, and the optimal value of the Lagrange multiplier is iteratively derived based on the known level of uncertainty in the signal DOA. The proposed implementation based on iterative minimization eliminates the covariance matrix inversion estimation at a comparable cost with that of the existing LSCMA. We present a theoretical analysis of our proposed algorithm in terms of convergence, SINR performance, array beampattern gain, and complexity cost in the presence of random steering vector mismatches. In contrast to the linearly constrained LSCMA, the proposed algorithm provides excellent robustness against the signal steering vector mismatches, yields improved signal capture performance, has superior performance on SINR improvement, and enhances the array system performance under random perturbations in sensor parameters. The on-line implementation and significant SINR enhancement support the practicability of the proposed algorithm. The numerical experiments have been carried out to demonstrate the superiority of the proposed algorithm on beampattern control and output SINR enhancement compared with linearly constrained LSCMA.