arxiv_ml 70% Match Research Paper Signal Processing Engineers,Radar/Sonar System Designers,Wireless Communication Engineers,Researchers in Array Signal Processing 2 weeks ago

Covariance Matrix Construction with Preprocessing-Based Spatial Sampling for Robust Adaptive Beamforming

computer-vision › 3d-vision

📄 Abstract

Abstract: This work proposes an efficient, robust adaptive beamforming technique to deal with steering vector (SV) estimation mismatches and data covariance matrix reconstruction problems. In particular, the direction-of-arrival(DoA) of interfering sources is estimated with available snapshots in which the angular sectors of the interfering signals are computed adaptively. Then, we utilize the well-known general linear combination algorithm to reconstruct the interference-plus-noise covariance (IPNC) matrix using preprocessing-based spatial sampling (PPBSS). We demonstrate that the preprocessing matrix can be replaced by the sample covariance matrix (SCM) in the shrinkage method. A power spectrum sampling strategy is then devised based on a preprocessing matrix computed with the estimated angular sectors' information. Moreover, the covariance matrix for the signal is formed for the angular sector of the signal-of-interest (SOI), which allows for calculating an SV for the SOI using the power method. An analysis of the array beampattern in the proposed PPBSS technique is carried out, and a study of the computational cost of competing approaches is conducted. Simulation results show the proposed method's effectiveness compared to existing approaches.

Authors (3)

Saeed Mohammadzadeh

Rodrigo C. de Lamare

Yuriy Zakharov

Submitted

September 30, 2025

arXiv Category

eess.SP

arXiv PDF

Key Contributions

This work proposes an efficient and robust adaptive beamforming technique that addresses steering vector estimation mismatches and covariance matrix reconstruction issues. It achieves this by adaptively estimating interfering source DoAs, reconstructing the IPNC matrix using PPBSS, and employing a shrinkage method with a modified preprocessing matrix, leading to improved performance in the presence of interference and SV errors.

Business Value

Enhances the performance and reliability of radar, sonar, and communication systems by effectively mitigating interference and improving signal reception, leading to better target detection and communication quality.

Paper Metadata

Innovation Type

Algorithmic Improvement

Deployment Feasibility

High, as it builds upon established signal processing techniques for beamforming and covariance estimation, implementable on specialized hardware.

Limitations Addressed

Steering vector (SV) estimation mismatches,Data covariance matrix reconstruction problems,Performance degradation due to interference and SV errors

Performance Gains

Demonstrates improved robustness and efficiency in adaptive beamforming compared to methods that do not explicitly handle SV mismatches and reconstruct the covariance matrix robustly.

Technical Tags

Adaptive BeamformingCovariance Matrix ReconstructionDirection-of-Arrival (DoA) EstimationSteering Vector (SV) MismatchInterference-Plus-Noise Covariance (IPNC) MatrixPreprocessing-Based Spatial Sampling (PPBSS)Shrinkage MethodSignal ProcessingArray Signal ProcessingRobustness

Research Topics

Array Signal ProcessingAdaptive FilteringRobust EstimationInterference MitigationSignal Detection

Methods & Architectures

DoA Estimation of Interfering SourcesGeneral Linear Combination AlgorithmPreprocessing-Based Spatial Sampling (PPBSS)Shrinkage MethodPower Spectrum Sampling StrategyCovariance Matrix Estimation

Applications & Tasks

Radar Systems Sonar Systems Wireless Communications Sensor Networks Medical Imaging (ultrasound) Robustness ImprovementParameter EstimationInterference SuppressionCovariance Matrix Estimation Adaptive BeamformingIPNC Matrix ReconstructionSV EstimationInterference DoA Estimation

Related Fields

Electrical EngineeringSignal ProcessingAerospace EngineeringDefense TechnologyTelecommunications

Keywords

adaptive beamformingcovariance matrixDoA estimationrobustnessinterference suppressionspatial samplingsteering vectorsignal processingarray processingIPNC matrix

Academic Context

#Array Signal Processing#Adaptive Filtering#Robust Estimation#Interference Mitigation#Signal Detection

Commercial Potential

Potential Products

Advanced radar signal processing unitsEnhanced sonar systemsNext-generation wireless communication receivers

Target Industries

DefenseAerospaceMaritimeTelecommunicationsAutomotive (ADAS)

Use Case Examples

Improving target detection in radar systems operating in cluttered environments with multiple jammers.Enhancing underwater acoustic communication by suppressing interfering noise sources.

Competitive Edge

Provides a more robust and efficient method for adaptive beamforming by explicitly addressing covariance matrix reconstruction and SV mismatches, potentially outperforming traditional methods in challenging environments.

Market Opportunity

Significant, driven by defense, telecommunications, and autonomous systems requiring advanced sensing.

Revenue Models

Integration into hardware/software productslicensing of algorithms.

Resource Requirements

Compute Needs

Moderate, involving matrix operations and iterative estimation processes.

Data Requirements

Requires multi-snapshot data from sensor arrays.

Deployment Constraints

Performance depends on the accuracy of DoA estimation and the number of available snapshots. Computational complexity can be a factor in real-time systems.

Scalability

Scalable to different array sizes and numbers of sources, with complexity increasing polynomially with array aperture.

Production Readiness

Maturity Level

Research

Time to Market

2-4 years

Patent Potential

Moderate, for the novel PPBSS technique and its integration into adaptive beamforming.

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