Research on micro-Doppler feature of spatial target

Ji, Zhenyuan; Hu, Encheng; Zhang, Yun; Jin, Hongyan

doi:10.1186/s13638-017-0963-7

Cited by 5 publications

(4 citation statements)

References 9 publications

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“…To solve the problem of unknown motion states, scholars have proposed many algorithms to suppress and separate the micro-Doppler effect, including time-frequency analysis and frequency decomposition. The time-frequency analysis introduces a threshold to separate the frequency components in the time-frequency map, enabling the separation of the main echo and the echo containing the micro-Doppler effect 11 – 13 However, the time-frequency analysis is overly dependent on the window function, resulting in the mutual restriction between the temporal and frequency resolutions.…”

Section: Introductionmentioning

confidence: 99%

“…The time-frequency analysis introduces a threshold to separate the frequency components in the time-frequency map, enabling the separation of the main echo and the echo containing the micro-Doppler effect. [11][12][13] However, the time-frequency analysis is overly dependent on the window function, resulting in the mutual restriction between the temporal and frequency resolutions. In addition, some main signals of the target may be removed during the signal separation, leading to diminished main energy and sparse aperture.…”

Section: Introductionmentioning

confidence: 99%

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Study on the micro-Doppler separation method of bistatic inverse synthetic aperture radar targets with rotating parts based on complex variational mode decomposition

Zhu¹,

Hu²,

Guo³

et al. 2022

J. Appl. Rem. Sens.

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In bistatic inverse synthetic aperture radar (Bi-ISAR) imaging of targets with rotating components, the micro-Doppler effect generated by rotating components can produce interference bands in azimuth resolution, seriously affecting the imaging results and causing difficulties in target recognition. A unique Bi-ISAR target micro-Doppler separation method with rotating components is proposed by introducing the complex variational mode decomposition (CVMD) method. First, the echo signal is decomposed into different intrinsic mode functions (IMFs) by CVMD for the Bi-ISAR imaging target with rotating parts. Then, IMFs are divided into main and micromotion parts by setting the energy threshold. The IMFs belonging to the main part are extracted, and the imaging is performed using the range-Doppler algorithm. The simulation results show that CVMD outperforms the complex empirical mode decomposition algorithm and the complex local mean decomposition algorithm in the Doppler separation of Bi-ISAR targets with rotating components. In addition, CVMD exhibits good robustness and provides innovative ideas for future research on micro-Doppler separation technology.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Study on the micro-Doppler separation method of bistatic inverse synthetic aperture radar targets with rotating parts based on complex variational mode decomposition

Zhu¹,

Hu²,

Guo³

et al. 2022

J. Appl. Rem. Sens.

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“…For space targets, it is important to conduct identifications for these interesting components, such as cabin and solar panels in the event of their aberrancy. Since inverse synthetic aperture radar (ISAR) provides high-quality twodimensional (2D) image for space targets [1], it becomes possible to analyze characteristics of partial interesting components. In space security-related reconnaissance and surveillance, there are a number of issues.…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional reconstruction for space targets with multistatic inverse synthetic aperture radar systems

Zhao

Zhang

Jiu

et al. 2019

EURASIP J. Adv. Signal Process.

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In this paper, a three-dimensional (3D) reconstruction algorithm is proposed for space targets with multistatic inverse synthetic aperture radar (ISAR) systems. In the proposed algorithm, target 3D geometry can be obtained by solving the projection equations between the target 3D geometry and ISAR images. Specially, it is no need to perform cross-range scaling. To obtain the projection equations, the algorithm consists of two steps: establishing projection matrix and associating scattering centers. Firstly, observation angles of sensor can be estimated by kinematic formulas and coordinate systems transformation. Using azimuth and elevation angles of sensor relative to target, the projection matrix from target 3D geometry to ISAR images is established. Secondly, an association cost function based on projective transform and epipolar geometry is developed. As the cost function is an assignment with 0-1 linear programming, the Jonker-Volgenant algorithm is used to build a one-to-one correspondence between two scattering centers. Numerical results show the efficiency of the proposed algorithm.

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“…In Table 3 are given the parameters of transponders used in UAV [18,19]. After the detection and identification of an object, surveillance systems further recognize it, and then, if necessary, follow the object's trajectory.…”

Section: Introductionmentioning

confidence: 99%