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Kvantovaya Elektronika, 2006, Volume 36, Number 4, Pages 339–342 (Mi qe13147)  

This article is cited in 11 scientific papers (total in 11 papers)

Optical fibres and waveguides

Correlation method for processing speckles of signals from single-fibre multimode interferometers by using charge-coupled devices

Yu. N. Kulchina, O. B. Vitrikb, A. D. Lantsovb

a Presidium of Far East Branch, Russian Academy of Sciences, Vladivostok
b Far-Eastern State Technical University, Vladivostok

Abstract: The correlation method for processing signals from a single-fibre multimode interferometer by using a digital charge-coupled device is studied experimentally and theoretically. Optimal conditions are determined for recording multimode interference patterns with charge-coupled devices. It is found that the nonlinearity of characteristics of such devices affects the results of correlation measurements. The method for eliminating this influence is proposed. The correlation method considered in the paper allows one to measure a linear deformation of the interferometer within 0–80 μm with an accuracy of ~±3 μm for typical multi-mode fibres with the core diameter 50 μm.

Full text: PDF file (131 kB)

English version:
Quantum Electronics, 2006, 36:4, 339–342

Bibliographic databases:

PACS: 07.60.Vg, 07.60.Ly
Received: 20.10.2005
Revised: 12.01.2006

Citation: Yu. N. Kulchin, O. B. Vitrik, A. D. Lantsov, “Correlation method for processing speckles of signals from single-fibre multimode interferometers by using charge-coupled devices”, Kvantovaya Elektronika, 36:4 (2006), 339–342 [Quantum Electron., 36:4 (2006), 339–342]

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  • http://mi.mathnet.ru/eng/qe13147
  • http://mi.mathnet.ru/eng/qe/v36/i4/p339

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    Citing articles on Google Scholar: Russian citations, English citations
    Related articles on Google Scholar: Russian articles, English articles

    This publication is cited in the following articles:
    1. Yu. N. Kulchin, O. B. Vitrick, A. D. Lantsov, V. A. Vorobyev, Yu. N. Moskvin, Optoelectron Instrument Proc, 44:3 (2008), 264  crossref
    2. Yu. N. Kulchin, O. B. Vitrik, A. D. Lantsov, Meas Tech, 2010  crossref  scopus
    3. Yu. N. Kul’chin, O. B. Vitrik, A. D. Lantsov, N. P. Kraeva, Optoelectron Instrument Proc, 46:3 (2010), 282  crossref
    4. Yu. N. Kulchin, O. B. Vitrik, A. D. Lantsov, Meas Tech, 2010  crossref  scopus
    5. Yu. N. Kulchin, O. B. Vitrik, A. D. Lantsov, N. V. Makarova, A. Yu. Zhizhchenko, Meas Tech, 2012  crossref  isi  elib  scopus
    6. O. I. Kotov, I. E. Chapalo, A. V. Medvedev, Tech. Phys. Lett, 40:6 (2014), 509  crossref  adsnasa  isi  elib  scopus
    7. Quantum Electron., 45:10 (2015), 979–988  mathnet  crossref  isi  elib
    8. Varyshchuk V., Bobitski Ya., 2016 13th International Conference on Modern Problems of Radio Engineering. Telecommunications and Computer Science (TCSET) (Lviv, Ukraine), IEEE, 2016, 399–401  crossref  isi  scopus
    9. Varyshchuk V., Bobitski Y., Poisel H., Opto-Electron. Rev., 25:1 (2017), 19–23  crossref  isi  scopus
    10. Maksimova L.A., Ryabukho P.V., Mysina N.Yu., Lyakin D.V., Ryabukho V.P., Opt. Spectrosc., 124:4 (2018), 549–559  crossref  isi  scopus
    11. Petrov V A., Chapalo I.E., Bisyarin M.A., Kotov I O., Appl. Optics, 59:33 (2020), 10422–10431  crossref  isi  scopus
  • Квантовая электроника Quantum Electronics
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