Antenna Pattern Calibration Method for Phased Array of High-Frequency Surface Wave Radar Based on First-Order Sea Clutter

Li, Hongbo; Liu, Aijun; Yang, Qiang; Yu, Changjun; Lyv, Zhe

doi:10.3390/rs15245789

Remote Sensing

2023

DOI: 10.3390/rs15245789

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Antenna Pattern Calibration Method for Phased Array of High-Frequency Surface Wave Radar Based on First-Order Sea Clutter

Hongbo Li,

Aijun Liu,

Qiang Yang

et al.

Abstract: The problem of accurate source localization has been an area of focus in high-frequency surface wave radar (HFSWR) applications. However, antenna pattern distortion (APD) decreases the direction-of-arrival (DOA) estimation performance of the multiple signal classification (MUSIC) algorithm. Up to now, limited studies have been conducted on the calibration of antenna pattern distortion for phased arrays in HFSWR. In this paper, we first analyze the effect of APD on the performance of the MUSIC algorithm through… Show more

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2024

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Combination of the biologically inspired coupled system and high‐frequency surface wave radar at signal level

Li,

Liu,

Yang

et al. 2024

IET Radar Sonar & Navi

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Virtual aperture extension of small aperture array has attracted wide attention in high‐frequency surface wave radar (HFSWR). A biologically inspired coupled (BIC) system is employed to virtually extend the array aperture. However, the existing researches on BIC only consider the array signal processing model and do not combine it with actual radar signal principle. To indeed apply the BIC system to HFSWR, two detailed methods which combine the BIC and HFSWR at signal level are proposed. A three‐dimensional signal model of HFSWR considering array processing was established and the entire signal processing was derived. Then, two combination methods, namely fast‐time domain (FTD)‐BIC and slow‐time domain (STD)‐BIC are proposed. The former implements the BIC before fast‐time processing, while the latter implements the BIC before slow‐time processing. The authors demonstrate that they can virtually extend the array aperture without affecting the target detection. Meanwhile, their capabilities in multi‐target scenarios are analysed and satisfactory conclusions are obtained. By numerical simulations and experiments, the array aperture and range‐Doppler (RD) spectrum of the standard HFSWR and BIC‐HFSWR are compared. The results show that while the performance of their RD spectrum is almost the same, BIC‐HFSWR has an enlarged virtual aperture than standard HFSWR.

show abstract

Combination of the biologically inspired coupled system and high‐frequency surface wave radar at signal level

Li,

Liu,

Yang

et al. 2024

IET Radar Sonar & Navi

View full text Add to dashboard Cite

show abstract

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Antenna Pattern Calibration Method for Phased Array of High-Frequency Surface Wave Radar Based on First-Order Sea Clutter

Cited by 1 publication

References 34 publications

Combination of the biologically inspired coupled system and high‐frequency surface wave radar at signal level

Combination of the biologically inspired coupled system and high‐frequency surface wave radar at signal level

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