Ghost Fiber Optic 3D Endoscopy

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Resumo

A new type of ghost fiber optic endoscopy has been proposed to obtain ghost images of three-dimensional optically transparent objects. The method is based on spatial and temporal correlation of light beams formed in a bundle of single-mode fibers exposed in the transverse direction to femtosecond laser pulses. Resolution in the depth of an object is ensured by an original algorithm to reconstruct images, which involves both the properties of femtosecond radiation and the features of light propagation in an inhomogeneous scattering medium. The effectiveness of the proposed method has been confirmed by a numerical simulation by an example of an octahedron with a layered structure.

Sobre autores

A. Belinskiy

Faculty of Physics, Moscow State University

Email: belinsky@physics.msu.ru
119991, Moscow, Russia

P. Gostev

Faculty of Physics, Moscow State University

Email: gostev.pavel@physics.msu.ru
119991, Moscow, Russia

S. Magnitskiy

Faculty of Physics, Moscow State University

Email: sergeymagnitskiy@gmail.com
119991, Moscow, Russia

A. Chirkin

Faculty of Physics, Moscow State University

Autor responsável pela correspondência
Email: aschirkin@physics.msu.ru
119991, Moscow, Russia

Bibliografia

  1. M. P. Edgar, G.M. Gibson, M. J. Padgett, Nature Photon. 13, 13 (2019).
  2. M. F. Duarte, M.A. Davenport, D. Takhar, J.N. Laska, T. Sun, K.F. Kelly, and R.G. Baraniuk, IEEE Sig. Pro. Mag. 25, 83 (2008).
  3. Z. Zhang, X. Ma, and J. Zhong, Nat. Commun. 6, 1 (2015).
  4. Z. Zhang, X. Wang, G. Zheng, and J. Zhong, Opt. Express 25, 19619 (2017).
  5. L. Martınez-Le'on, P. Clemente, Y. Mori, V. Climent, J. Lancis, and E. Tajahuerce, Opt. Express 25, 4975 (2017).
  6. B. Lochocki, A. Gambın, S. Manzanera, E. Irles, E. Tajahuerce, J. Lancis, and P. Artal, Optica 3, 1056 (2016).
  7. R. Dutta, S. Manzanera, A. Gambın-Regadera, E. Irles, E. Tajahuerce, J. Lancis, and P. Artal, Biomed. Opt. Express 10, 4159 (2019).
  8. N. Radwell, K. J. Mitchell, G.M. Gibson, M. P. Edgar, R. Bowman, and M. J. Padgett, Optica 1, 285 (2014).
  9. P. Clemente, V. Dur'an, E. Tajahuerce, P. Andr'es, V. Climent, and J. Lancis, Opt. Lett. 38, 2524 (2013).
  10. P. Clemente, V. Duran, E. Tajahuerce, and J. Lancis, Phys. Rev. A 86, 041803 (2012).
  11. D.B. Phillips, M.-J. Sun, J.M. Taylor, M.P. Edgar, S.M. Barnett, G.M. Gibson, and M. J. Padgett, Sci. Adv. 3, e1601782 (2017).
  12. Z. Wei, J. Zhang, Z. Xu, Y. Liu, Y. Huang, and X. Fan, IEEE Photonics J. 11, 1 (2019).
  13. Y.Wang, F. Wang, R. Liu, P. Zhang, H. Gao, and F. Li, Opt. Express 27, 5973 (2019).
  14. F. Magalh˜aes, F. M. Ara'ujo, M. Correia, M. Abolbashari, and F. Farahi, Opt. Eng. 51, 071406 (2012).
  15. K. Shibuya, T. Minamikawa, Y. Mizutani, H. Yamamoto, K. Minoshima, T. Yasui, and T. Iwata, Opt. Express 25, 21947 (2017).
  16. B. Sun, M. P. Edgar, R. Bowman, L.E. Vittert, S. Welsh, A. Bowman, and M. J. Padgett, Science 340, 844 (2013).
  17. Z. Zhang, S. Liu, J. Peng, M. Yao, G. Zheng, and J. Zhong, Optica 5, 315 (2018).
  18. C. Zhang, W. He, B. Han, M. Liao, D. Lu, X. Peng, and C. Xu, Opt. Express 27, 13469 (2019).
  19. Z. Zhang, S. Jiao, M. Yao, X. Li, and J. Zhong, Opt. Express 26, 14578 (2018).
  20. Д.П. Агапов, И.А. Беловолов, П.П. Гостев, С.А. Магницикй, Д.Н. Фроловцев, А.С. Чиркин, ЖЭТФ 162, 215 (2022)
  21. D. Agapov, I. Belovolov, P. Gostev, S. Magnitskii, D. Frolovtsev, and A. Chirkin, JETP 135(2), 188 (2022).
  22. A. Gatti, E. Brambilla, M. Bache, and L.A. Lugiato, Phys. Rev. A 70, 013802 (2004).
  23. Д.А. Балакин, Д.П. Агапов, П.П. Гостев, С.А. Магницкий, Д.Н. Фроловцев, А.С. Чиркин,ЖЭТФ 162, 569 (2022)
  24. D.A. Balakin, D.P. Agapov, P.P. Gostev, S.A. Magnitskiy, D.N. Frolovtsev, and A. S. Chirkin, JETP 135(6), 779 (2022).
  25. P.-A. Moreau, E. Toninelli, T. Gregory, and M. J. Padgett, Laser and Photonics Reviews 12, 1700143 (2018).
  26. Ю.П. Пытьев, Методы математического моделирования измерительно-вычислительных систем, Физматлит, М. (2012).
  27. D. Balakin, A. Belinsky, and A. Chirkin, Quant. Inform. Proc. 18, 1 (2019).
  28. A. Chirkin, P. Gostev, D. Agapov, and S. Magnitskiy, Las. Phys. Lett. 15, 115404 (2018).
  29. S. Magnitskiy, D. Agapov, and A. Chirkin, Opt. Lett. 45, 3641 (2020).
  30. S. Magnitskiy, D. Agapov, I. Belovolov, P. Gostev, D. Frolovtsev, and A. Chirkin, Moscow Univer. Phys. Bull. 76, 424 (2021).
  31. S. Magnitskiy, D. Agapov, and A. Chirkin, Opt. Lett. 47, 754 (2022).
  32. А.В. Белинский, Д.Н. Клышко, ЖЭТФ 105, 487 (1994).
  33. B. I. Erkmen and J.H. Shapiro, Adv. Opt. Phot. 2, 405 (2010).
  34. А.В. Белинский,Журнал научной и прикладной фотографии и кинематографии 3, 198 (1983).
  35. P.P. Gostev, ghost_images, https://github.com/vongostev/ghost_images.

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