Radar Pulse Compression with Optimized Weighting Window for SAR Receivers

Hussein, Khalid F. A.; Helmy, Asmaa O.; Mohra, Ashraf S.

doi:10.1007/s11277-022-09774-z

Cited by 6 publications

(2 citation statements)

References 17 publications

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“…In other words, a compressed radar pulse that includes the required frequency content can be used for efficient detection, classification, and identification of the detected flying fighter jet or the target that the missile is looking for. A frequency-chirped rectangular pulse can be used as the radar pulse for this purpose [9]. Such a pulse can have the following general expression.…”

Section: Construction Of the Distinguishing Radar Pulsementioning

confidence: 99%

Electromagnetic Simulation for Robust Recognition Algorithm of Radar Target by Homing Missiles

Abd-Elfattah¹,

Hussein²,

Farahat³

et al. 2022

PIER B

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A novel signal processing scheme for identification of jet fighter targets by the onboard radar of active and hybrid homing missiles is proposed in the present work. For a specific target, the frequencies of the internal resonances of the cavity-backed apertures existing as the air-inlet pipes of the jet engine are used to construct an interior signature function for the proposed target identification scheme. For the purpose of quantitative description and assessment of the proposed scheme, electromagnetic simulation is used where the air-inlet pipe is modeled as an open-ended conducting cylinder with a number of radial conducting blades placed inside the cylindrical cavity near the open end. The transmitted radar pulse is formed by frequency chirping using linear frequency modulation (LFM) to include the frequencies in the band 1.0-2.0 GHz with high sweep resolution. The selected frequency band is wide enough to distinguish among various jet fighter targets. The CST R ⃝ simulator is used to evaluate the radar cross section (RCS) of the open-ended pipe model with the internal blades due to an incident chirped pulsed plane wave as mentioned above over the frequency band 1.0-2.0 GHz. The proposed target identification algorithm is mathematically described and computationally applied to identify different targets with different dimensions of the jet engine pipe. The effect of the additive white Gaussian noise (AWGN) on the correctness of the target identification decision using the proposed scheme is investigated by calculating the false alarm rate (FAR) with varying the signal-to-noise ratio (SNR). The numerical examinations show that the proposed algorithm succeeds in taking the correct decision regarding the target identification with FAR < 10% for SNR ≥ 12 dB.

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Section: Construction Of the Distinguishing Radar Pulsementioning

confidence: 99%

Electromagnetic Simulation for Robust Recognition Algorithm of Radar Target by Homing Missiles

Abd-Elfattah¹,

Hussein²,

Farahat³

et al. 2022

PIER B

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“…Sidelobe suppression has been a common subject of research throughout its existence as the typical processing methods used are all imperfect recreations of the imaged scene. Recent research areas include receiver design [ 3 ], signal processing [ 4 ], and collection methodology [ 5 ]. As discussed multistatic SAR involves multiple sensing systems transmitting and/or receiving with techniques required to fuse these data into a single collection.…”

Section: Introductionmentioning

confidence: 99%

Sidelobe Suppression Techniques for Near-Field Multistatic SAR

Price

Moate

André

et al. 2023

Sensors

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Multirotor Unmanned Air Systems (UAS) represent a significant improvement in capability for Synthetic Aperture Radar (SAR) imaging when compared to traditional, fixed-wing, platforms. In particular, a swarm of UAS can generate significant measurement diversity through variation of spatial and frequency collections across an array of sensors. In such imaging schemes, the image formation step is challenging due to strong extended sidelobe; however, were this to be effectively managed, a dramatic increase in image quality is theoretically possible. Since 2015, QinetiQ have developed the RIBI system, which uses multiple UAS to perform short-range multistatic collections, and this requires novel near-field processing to mitigate the high sidelobes observed and form actionable imagery. This paper applies a number of algorithms to assess image reconstruction of simulated near-field multistatic SAR with an aim to suppress sidelobes observed in the RIBI system, investigating techniques including traditional SAR processing, regularised linear regression, compressive sensing. In these simulations presented, Elastic net, Orthogonal Matched Pursuit, and Iterative Hard Thresholding all show the ability to suppress sidelobes while preserving accuracy of scatterer RCS. This has also lead to a novel processing approach for reconstructing SAR images based on the observed Elastic net and Iterative Hard Thresholding performance, mitigating weaknesses to generate an improved combined approach. The relative strengths and weaknesses of the algorithms are discussed, as well as their application to more complex real-world imagery.

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