References

omna

Омский научный вестник

Omsk Scientific Bulletin

1813-82252541-7541

Омский государственный технический университет

10.25206/1813-8225-2024-192-108-116

GYUTJM

omna-114

Research Article

ЭЛЕКТРОНИКА, ФОТОНИКА, ПРИБОРОСТРОЕНИЕ И СВЯЗЬ

ELECTRONICS, PHOTONICS, APPLIANCE AND COMMUNICATIONS

Анализ характеристик рассеяния Мандельштама–Бриллюэна в разновидностях эрбиевых оптических волокон

nalysis of the characteristics of Mandelstam–Brillouin scattering in varieties of erbium optical fibers

https://orcid.org/0000-0002-7019-1784

Богачков

И. В.

Bogachkov

I. V.

БОГАЧКОВ Игорь Викторович, доктор технических наук, доцент, профессор кафедры «Средства связи и информационная безопасность»

г. Омск

AuthorID (РИНЦ): 276415

AuthorID (SCOPUS): 3699775670

ResearcherID: A-7770-2015

BOGACHKOV Igor Viktorovich, Doctor of Technical Sciences, Associate Professor, Professor of Communications and Information Security Department

Omsk

AuthorID (RSCI): 276415AuthorID (SCOPUS): 3699775670

ResearcherID: A-7770-2015

bogachkov@mail.ru

Омский государственный технический университетРоссияOmsk State Technical UniversityRussian Federation

2024

30122024

04108116

2024

Богачков И.В.

Bogachkov I.V.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://onv.omgtu.ru/jour/article/view/114

В этой работе представлены результаты тестирования параметров рассеяния Мандельштама–Бриллюэна для нескольких видов оптических волокон, легированных ионами эрбия и церия. Приведены полученные бриллюэновские рефлектограммы разных типов. Представлены частотные характеристики бриллюэновского рассеяния. Сделаны оценки начальных значений бриллюэновского частотного сдвига и поведения рефлектограмм уровня обратно отраженного сигнала для исследованных разновидностей волокон. Проведён сравнительный анализ полученных параметров различных видов эрбиевых оптических волокон.

The research presents the results of testing the Mandelstam–Brillouin scattering parameters for several types of optical fibers doped with erbium and cerium ions. The obtained Brillouin reflectograms of different types are shown. The frequency characteristics of Brillouin scattering are drawn. Estimates of the initial values of the Brillouin frequency shift and the behavior of the reflectograms of the back reflected signal level for the studied fiber varieties are presented. A comparative analysis of the obtained parameters of various types of erbium optical fibers is carried out.

рассеяния Мандельштама–Бриллюэнабриллюэновская рефлектометрияэрбиевое оптическое волокнооптическое волокно с добавлением эрбия и церияпрофиль спектра бриллюэновского рассеяниябриллюэновский частотный сдвигклассификация волокон

Mandelstam–Brillouin backscatter spectrumBrillouin reflectometryerbium optical fiberoptical fiber with addition of erbium and ceriumBrillouin spectrum profileBrillouin frequency shiftclassification of fibers

References1

Богачков И. В. Определение разновидностей оптических волокон и ранняя диагностика их физического состояния на основе анализа характеристик рассеяния Мандельштама–Бриллюэна // Омский научный вестник. 2024. № 2 (190). С. 107–116. DOI: 10.25206/1813-8225-2024-190-107-116. EDN: XDUAQS.

Bogachkov I. V. Opredeleniye raznovidnostey opticheskikh volokon i rannyaya diagnostika ikh fizicheskogo sostoyaniya na osnove analiza kharakteristik rasseyaniya Mandel’shtama– Brillyuena [Determination of optical fiber varieties and early diagnosis of their physical condition based on the analysis of Mandelstam–Brillouin backscatter parameters] // Omskiy nauchnyy vestnik. Omsk Scientific Bulletin. 2024. No. 2 (190). P. 107–116. DOI: 10.25206/1813-8225-2024-190-107-116. EDN: XDUAQS. (In Russ.).

Bogachkov I. V. Researches of the Mandelstam–Brillouin backscatter spectrum in the erbium-doped optical fiber // T-comm. 2017. Vol. 11, № 6. P. 59–63.

Bogachkov I. V. Researches of the Mandelstam–Brillouin backscatter spectrum in the erbium-doped optical fiber // T-comm. 2017. Vol. 11, no. 6. P. 59–63. (In Engl.).

Ruffin A. B., Li M.-J., Chen X. [et al.]. Brillouin gain analysis for fibers with different refractive indices // Optics Letters. 2005. Vol. 30 (23). P. 3123–3125. DOI: 10.1364/ol.30.003123.

Ruffin A. B., Li M.-J., Chen X. [et al.]. Brillouin gain analysis for fibers with different refractive indices // Optics Letters. 2005. Vol. 30 (23). P. 3123–3125. DOI: 10.1364/ol.30.003123. (In Engl.).

Krivosheev A. I., Konstantinov Y. A., Barkov F. L. [et al.]. Comparative analysis of the Brillouin frequency shift determining accuracy in extremely noised spectra by various correlation methods // Instruments and experimental techniques. 2021. Vol. 64 (5). P. 715–719. DOI: 10.1134/S0020441221050067. EDN: UVUFPP.

Koyamada Y., Sato S., Nakamura S. [et al.]. Simulating and designing Brillouin gain spectrum in single-mode fibers // Lightwave Technol. 2004. Vol. 22 (2). P. 631–639. DOI: 10.1109/JLT.2003.822007.

Koyamada Y., Sato S., Nakamura S. [et al.]. Simulating and designing Brillouin gain spectrum in single-mode fibers // Lightwave Technol. 2004. Vol. 22 (2). P. 631–639. DOI: 10.1109/ JLT.2003.822007. (In Engl.).

Belokrylov M. E., Claude D., Konstantinov Y. A. [et al.]. Method for increasing the signal-to-noise ratio of Rayleigh backscattered radiation registered by a frequency domain optical reflectometer using two-stage erbium amplification // Instruments and Experimental Techniques. 2023. Vol. 66 (5). P. 761–768. DOI: 10.1134/S0020441223050172.

Krivosheev A. I., Barkov F. L., Konstantinov Y. A. [et al.]. State-of-the-Art methods for determining the frequency shift of Brillouin scattering in fiber-optic metrology and sensing // Instruments and Experimental Techniques. 2022. Vol. 65 (5). P. 687–710. DOI: 10.1134/S0020441222050268.

Kobyakov A., Sauer M., Chowdhury D. Stimulated Brillouin scattering in optical fibers // Advances in Optics and Photonics. 2010. Vol. 2 (1). P. 1–59. DOI: 10.1364/AOP.2.000001.

Kobyakov A., Sauer M., Chowdhury D. Stimulated Brillouin scattering in optical fibers // Advances in Optics and Photonics. 2010. Vol. 2 (1). P. 1–59. DOI: 10.1364/AOP.2.000001. (In Engl.).

Bao X., Chen L. Recent progress in Brillouin scattering based fiber sensors // Sensors. 2011. Vol. 11. P. 4152–4187. DOI: 10.3390/s110404152.

Bao X., Chen L. Recent progress in Brillouin scattering based fiber sensors // Sensors. 2011. Vol. 11. P. 4152–4187. DOI: 10.3390/s110404152. (In Engl.).

Bogachkov I. V., Trukhina A. I., Gorlov N. I. The study of the Mandelstam–Brillouin scattering in erbium optical fibers // Systems of signals generating and processing in the field of onboard communications – Proceedings. Moscow, 2019. P. 1–6. DOI: 10.1109/SOSG.2019.8706720. EDN: PXJTGI.

Bogachkov I. V., Gorlov N. I. Researches of the Mandelstam–Brillouin backscatter features in the erbium-doped optical fiber // 14th International Conference on Actual Problems of Electronic Instrument Engineering (APEIE–2018): Proceedings. In 8 vols. Novosibirsk, 2018. Vol. 1, Part 1. P. 322–326. DOI: 10.1109/APEIE.2018.8545024. EDN: MBEXYM.

Bogachkov I. V. The experimental researches of the Mandelstam–Brillouin scatter characteristics in erbium optical fibers of various kinds // T-comm. 2019. Vol. 13, № 4. P. 70–75.

Bogachkov I. V. The experimental researches of the Mandelstam–Brillouin scatter characteristics in erbium optical fibers of various kinds // T-comm. 2019. Vol. 13, no. 4. P. 70–75. (In Engl.).

Tartara L., Codemard C., Maran J. [et al.]. Full Modal Analysis of the Brillouin Gain Spectrum of an Optical Fiber // Optics Communications. 2009. Vol. 282 (2). P. 2431–2436. DOI: 10.1016/j.optcom.2009.03.012.

Dragic P. D. Estimating the effect of Ge doping on the acoustic damping coefficient via a highly Ge-doped MCVD silica fiber // Journal of the Optical Society of America B. 2009. Vol. 26 (8). P. 1614–1620. DOI: 10.1364/JOSAB.26.001614.

Law P.-C., Liu Y.-Sh., Croteau A., Dragic P. D. Acoustic coefficients of P2 O5 -doped silica fiber: acoustic velocity, acoustic attenuation, and thermo-acoustic coefficient // Optical Materials Express. 2011. Vol. 1, № 4. P. 686–699. DOI: 10.1364/OME.1.000686.

Zou W., He Z., Hotate K. Experimental study of Brillouin scattering in fluorine-doped single-mode optical fibers // Optics Express. 2008. Vol. 16. P. 18804–18812. DOI: 10.1364/OE.16.018804.

Zou W., He Z., Hotate K. Experimental study of Brillouin scattering in fluorine-doped single-mode optical fibers // Optics Express. 2008. Vol. 16. P. 18804–18812. DOI: 10.1364/OE.16.018804. (In Engl.).

Gorshkov B. G., Yüksel K., Fotiadi A. A. [et al.]. Scientific applications of distributed acoustic sensing: State-of-the-Art review and perspective // Sensors 2022. Vol. 22, № 1033. DOI: 10.3390/s22031033.

Gorshkov B. G., Yüksel K., Fotiadi A. A. [et al.]. Scientific applications of distributed acoustic sensing: State-of-the-Art review and perspective // Sensors 2022. Vol. 22, no. 1033. DOI: 10.3390/s22031033. (In Engl.).

Barkov F. L., Konstantinov Y. A., Krivosheev A. I. A novel method of spectra processing for Brillouin optical time domain reflectometry // Fibers. 2020. Vol. 8, № 9. P. 1–11. DOI: 10.3390/FIB8090060.

Barkov F. L., Konstantinov Y. A., Krivosheev A. I. A novel method of spectra processing for Brillouin optical time domain reflectometry // Fibers. 2020. Vol. 8, no. 9. P. 1–11. DOI: 10.3390/FIB8090060. (In Engl.).

Afshar S., Kalosha V. P., Bao X., Chen L. Enhancement of stimulated Brillouin scattering of higher-order acoustic modes in single-mode optical fiber // Optics Letters. 2005. Vol. 30 (20). P. 2685–2687. DOI: 10.1364/OL.30.002685.

Park K., Jeong Y. A quasi-mode interpretation of acoustic radiation modes for analyzing Brillouin gain of acoustically antiguiding optical fibers // Optics Express. 2014. Vol. 22, № 7. P. 2–13. DOI:10.1364/OE.22.007932.

The authors declare that there are no conflicts of interest present.