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Nick-named laser radars

  • Vasyl Molebny

    Vasyl Molebny is a Principal Scientist of the company and designer-in-chief of laser-based systems. He received his MS and PhD degrees from Natl Techn Univ of Ukraine and DSc degree from Moscow Altair Inst in 1991. In 1996, he was conferred the title Professor of Optics from Natl Univ. of Kyiv. His research interest include precision laser radar systems, information processing, wave front measurement and medical applications of lasers. He has more than 400 publications and 100 patents to his credit. He is a Member of the Acad of Technol Sci of Ukraine and also an SPIE Member and a Senior Member of the Opt Soc of America. He is the recipient of the National Prize of Russia and Glushkov Acad award.

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Published/Copyright: August 25, 2019
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Advanced Optical Technologies
From the journal Advanced Optical Technologies Volume 8 Issue 6

Abstract

In this article the laser-based technologies for remote sensing that use laser radar principles, but still known under other names like photonics radar, optical coherence tomography, aberrometry, etc., are reviewed A look into some examples of a variety of such nick-named instruments and technologies is proposed assessing the arguments of them, being the members of the laser radar family.

Keywords: aberrometry; laser radar; microradar; optical coherence tomography; photonics radar

About the author

Vasyl Molebny

Vasyl Molebny is a Principal Scientist of the company and designer-in-chief of laser-based systems. He received his MS and PhD degrees from Natl Techn Univ of Ukraine and DSc degree from Moscow Altair Inst in 1991. In 1996, he was conferred the title Professor of Optics from Natl Univ. of Kyiv. His research interest include precision laser radar systems, information processing, wave front measurement and medical applications of lasers. He has more than 400 publications and 100 patents to his credit. He is a Member of the Acad of Technol Sci of Ukraine and also an SPIE Member and a Senior Member of the Opt Soc of America. He is the recipient of the National Prize of Russia and Glushkov Acad award.

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Received: 2019-06-15
Accepted: 2019-07-26
Published Online: 2019-08-25
Published in Print: 2019-12-18

© 2019 THOSS Media & De Gruyter, Berlin/Boston

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https://doi.org/10.1515/aot-2019-0041
Keywords for this article
aberrometry; laser radar; microradar; optical coherence tomography; photonics radar

Articles in the same Issue

  1. Cover and Frontmatter
  2. Views
  3. Sixty years of advanced imaging at the French-German Research Institute of Saint-Louis: from the Cranz-Schardin camera to computational optics
  4. Community
  5. Conference Notes
  6. Topical Issue: Active Imaging
  7. Editorial
  8. Active imaging
  9. Review Article
  10. Nick-named laser radars
  11. Research Articles
  12. Experimental SWIR gated viewing in accumulation mode
  13. InGaAs APD matrix sensors for SWIR gated viewing
  14. Modelling and impact of the turbulence effect on flash and cumulative 2D active imaging system
  15. Laser-based imaging applications in turbid waters
  16. Review Article
  17. Reflectors in lighting design
  18. Research Articles
  19. A procedure for designing and manufacturing microstructured lenses used in automotive headlamps
  20. Fabrication of textured substrates for dye-sensitized solar cells using polydimethylsiloxane nanoimprint lithography
  21. 10.1515/aot-2019-0023
  22. 10.1515/aot-2018-0072
  23. 10.1515/aot-2019-0021
  24. Erratum
  25. Erratum to: Ultrafast Bessel beams: advanced tools for laser materials processing
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