Analysis of Hypersonic Platform-Borne SAR Imaging: A Physical Perspective

Song, Lihao; Bai, Bowen; Li, Xiaoping; Niu, Gezhao; Liu, Yanming; Zhao, Liang; Zhou, Hui

doi:10.3390/rs13234943

Cited by 4 publications

(2 citation statements)

References 33 publications

(65 reference statements)

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“…It absorbs energy, induces attenuation, alters phase, and may deviate the electromagnetic wave from its original path, causing intricate variations in received signals and potentially obscuring vital target information. This poses considerable challenges for radar remote sensing, detection, and communication of hypersonic targets [8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Charging Process in Dusty Plasma of Large-Size Dust Particles

Yue,

Li,

Guo

et al. 2024

Remote Sensing

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During reentry, the high temperatures experienced by near-space hypersonic vehicles result in surface ablation, generating ablative particles. These particles become part of a plasma, commonly referred to as a “dusty plasma sheath” in radar remote sensing. The dusty plasma model, integral in radar studies, involves extensive charge and dynamic interactions among dust particles. Previous derivations assumed that the dust particle radius significantly surpassed the Debye radius, leading to the neglect of dust radius effects. This study, however, explores scenarios where the dust particle radius is not markedly smaller than the Debye radius, thereby deducing the charging process of dusty plasma. The derived equations encompass the Debye radius, charging process, surface potential, and charging frequency, particularly considering larger dust particle radii. Comparative analysis of the dusty plasma model, both before and after modification, reveals improvements when dust particles approach or exceed the Debye length. In essence, our study provides essential equations for understanding dusty plasma under realistic conditions, offering potential advancements in predicting electromagnetic properties and behaviors, especially in scenarios where dust particles closely align with or surpass the Debye radius.

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Section: Introductionmentioning

confidence: 99%

Charging Process in Dusty Plasma of Large-Size Dust Particles

Yue,

Li,

Guo

et al. 2024

Remote Sensing

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“…When SBV-PRF technology is applied to the spaceborne squint sliding spotlight SAR, there are still problems of Doppler spectrum aliasing caused by squint angle and block varying non-uniform sampling in the azimuth-adjacent sub-aperture data [17][18][19]. Based on the characteristics of the SBV-PRF squint sliding spotlight SAR echo signal, a squint sliding spotlight SAR signal processing method combining SBV-PRF and sub-aperture division is proposed in this paper.…”

Section: Introductionmentioning

confidence: 99%

System Design and Signal Processing in Spaceborne Squint Sliding Spotlight SAR with Sub-Aperture Block-Varying PRF

Zhang

Huang

et al. 2023

Electronics

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To tackle the problems of Doppler spectrum, aliasing caused by azimuth beam scanning and azimuthal serious non-uniform sampling in squint sliding spotlight synthetic aperture radar (SAR) with varying repetition frequency technology, the azimuth sampling method of sub-aperture block-varying pulse repetition frequency (SBV-PRF) is proposed, where the sub-aperture division judgement makes the azimuth acquisition time of each sub-block small enough so that the Doppler bandwidth caused by the Doppler center change can be ignored. Based on the echo signal characteristics of a SBV-PRF transmission scheme, an azimuth pre-processing method combining SBV-PRF transmission scheme with sub-aperture division is proposed. Using this method, de-skewing is first performed on each set of sub-aperture data to eliminate the additional Doppler bandwidth introduced by the squint angle, and then the azimuth signal resampling is performed to ensure different sub-aperture data have the same sampling rate. The SBV-PRF technology reduces the difficulty of azimuth signal pre-processing while ensuring the complete acquisition of the complete echo data of the squint sliding spotlight mode. The effectiveness of the SBV-PRF system design and the signal processing method is verified by the point target echo simulation and imaging simulation results.

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Design of Analysis Platform for College Students' Physical Learning Effect Based on Data Mining Algorithm

Wang

2023

2023 IEEE International Conference on Integrated Circuits and Communication Systems (ICICACS)

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Analysis of Hypersonic Platform-Borne SAR Imaging: A Physical Perspective

Cited by 4 publications

References 33 publications

Charging Process in Dusty Plasma of Large-Size Dust Particles

Charging Process in Dusty Plasma of Large-Size Dust Particles

System Design and Signal Processing in Spaceborne Squint Sliding Spotlight SAR with Sub-Aperture Block-Varying PRF

Design of Analysis Platform for College Students' Physical Learning Effect Based on Data Mining Algorithm

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