3D Range-gated Imaging Method Based on Parabolic Envelope Inversion

SUN Lei;JIN Dongdong;JI Chunheng;PEI Chonglei;AN Hongbo

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  • Sponsored by: China Association for Science and Technology (CAST)

    Editor-In-Chief: Xu Yida

    ISSN 1000-1093

     

  • Hosted By: China Ordnance Society

    Published By: Acta Armamentarii

    CN 11-2176/TJ

Acta Armamentarii, a Chinese monthly journal, was first published in 1979. The journal is supervised by China Association for Science and Technology, sponsored by China Ordnance Society,and edited and published by Editorial Board of Acta Armamentarii. The Journal is included in all important domestic databases,and also collected by Engineering Index (EI, USA), Chemical Abstracts (CA, USA), Science Abstracts (SA, UK), Abstract Journal (AJ, Russia), and Current Bibliography on Science and Technology(CBST).Acta Armamentarii has been selected into the journal Of Ordnance Science and Technology (Weapons Industry) Field Of High Quality Scientific and Technological Periodical Classification Catalogue (2022 edition), ranking T1, and the journal of Automotive Engineering Field of High Quality Scientific and technological Periodical classification Catalogue, ranking T2.
Acta Armamentarii ›› 2022, Vol. 43 ›› Issue (8) : 1868-1873. DOI: 10.12382/bgxb.2021.0528
Paper

3D Range-gated Imaging Method Based on Parabolic Envelope Inversion

  • SUN Lei, JIN Dongdong, JI Chunheng, PEI Chonglei, AN Hongbo
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Abstract

3D range-gated imaging technology is of great significance in application fields such as 3D mapping, long-distance surveillance, navigation, and underwater target detection. The development of 3D range-gated super-resolution imaging technology and the frequently-used 3D inversion algorithms are introduced. On this basis, the 3D range-gated imaging method based on the parabolic envelope is studied. In terms of actual ranging accuracy, depth of field (DOF) of 3D imaging, real-time performance and the difficulty of system implementation, the proposed method is compared with the commonly used triangle and trapezoidal energy-related algorithms and verified by experiments. The results show that the the parabolic envelope-based 3D inversion algorithm reduces the system hardware index requirements, improves the actual ranging accuracy, and meets the demand for real-time large DOF 3D imaging, which demonstrates its good application prospects.

Key words

rangegating / 3Dimagingmethods / super-resolution / parabolicenvelope

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SUN Lei, JIN Dongdong, JI Chunheng, PEI Chonglei, AN Hongbo. 3D Range-gated Imaging Method Based on Parabolic Envelope Inversion. Acta Armamentarii. 2022, 43(8): 1868-1873 https://doi.org/10.12382/bgxb.2021.0528

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