Title :
A recursive least squares implementation for LCMP beamforming under quadratic constraint
Author :
Tian, Zhi ; Bell, Kristine L. ; Van Trees, Harry L.
Author_Institution :
Dept. of Electr. & Comput. Eng., Michigan Technol. Univ., Houghton, MI, USA
fDate :
6/1/2001 12:00:00 AM
Abstract :
Quadratic constraints on the weight vector of an adaptive linearly constrained minimum power (LCMP) beamformer can improve robustness to pointing errors and to random perturbations in sensor parameters. We propose a technique for implementing a quadratic inequality constraint with recursive least squares (RLS) updating. A variable diagonal loading term is added at each step, where the amount of loading has a closed-form solution. Simulations under different scenarios demonstrate that this algorithm has better interference suppression than both the RLS beamformer with no quadratic constraint and the RLS beamformer using the scaled projection technique, as well as faster convergence than LMS beamformers
Keywords :
adaptive filters; array signal processing; convergence of numerical methods; filtering theory; interference suppression; least squares approximations; LCMP beamforming; LMS; RLS beamformer; RLS updating; adaptive linearly constrained minimum power beamformer; array processing; closed-form solution; convergence; interference suppression; pointing errors robustness; quadratic constraints; quadratic inequality constraint; random perturbations; recursive least squares implementation; robust adaptive filtering; robustness control; scaled projection; sensor parameters; simulation results; simulations; uniform linear array; variable diagonal loading term; weight vector; Array signal processing; Closed-form solution; Interference constraints; Interference suppression; Least squares approximation; Least squares methods; Resonance light scattering; Robustness; Sensor arrays; Vectors;
Journal_Title :
Signal Processing, IEEE Transactions on
