Introduces the Universal Switching Beamformer that maintains an exponentially large set of covariance histories via a linear transition diagram and re-weights them by cumulative output power, with a proven regret bound to an oracle.
Adaptive Diagonal Loading using Krylov Subspaces for Robust Beamforming
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
Reliable adaptive beamforming is critical for large microphone arrays operating in highly dynamic acoustic environments. In scenarios characterized by fast-moving talkers and interferers, the available sample support for estimating the spatial correlation matrix is often snapshot-deficient. This deficiency degrades the White Noise Gain (WNG), leading to severe target signal cancellation. To ensure stable and robust beamforming, we previously proposed an adaptive diagonal loading method that leverages the Kantorovich inequality to guarantee the WNG remains strictly within specified bounds. However, accurately determining the smallest necessary loading level requires calculating the extreme eigenvalues of the spatial correlation matrix, a computationally expensive $\mathcal{O}(M^3)$ operation for large arrays. In this paper, we introduce a highly efficient $\mathcal{O}(kM^2)$ estimation technique using Lanczos iterations to build a small Krylov subspace. By projecting the correlation matrix onto a tridiagonal matrix of dimension $k \ll M$, we extract Ritz values that rapidly converge to the exact extreme eigenvalues. Our evaluations demonstrate that this Lanczos-accelerated approach achieves performance identical to exact Eigenvalue Decomposition (EVD), ensuring optimal interference suppression and strict WNG adherence at a fraction of the computational cost.
fields
eess.SP 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
A dynamic programming framework segments time series for adaptive Capon beamforming by minimizing output power with data-driven SCM windows to track moving interferers.
citing papers explorer
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A Switching Beamformer for Highly Non-Stationary Environments
Introduces the Universal Switching Beamformer that maintains an exponentially large set of covariance histories via a linear transition diagram and re-weights them by cumulative output power, with a proven regret bound to an oracle.
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Time Segmented Beamforming via Dynamic Programming: Theory and Implementation
A dynamic programming framework segments time series for adaptive Capon beamforming by minimizing output power with data-driven SCM windows to track moving interferers.