Method for Computing of Precision Positioning Scheme Parameters for MDM Channels Placement on Optical Fiber Core End

This work presents method for computing of precision spatial positioning scheme parameters for mode division multiplexing (MDM) system channels placement on excited optical fiber core end. We demonstrate results of calculations performed for 5-channel MDM system launching into few-mode optical fiber core end with reduced differential mode delay and core diameter 42 μm. It is noted that particular combination of injected mode field radius and precision offset provides transferring of the almost total lunched mode power to only one excited desired
guided fiber mode with the same azimuth order.

1. Richardson D.J., Fini J.M., Nelson L.E. Space-Division Multiplexing in Optical Fibers // Nature Photonics. 2013. Vol. 7. No 5. PP. 354–362.

2. Mizuno T., Takara H., Sano A., Miyamoto Yu. Dense Space-Division Multiplexed Transmission Systems Using Multi-Core and Multi-Mode Fiber // IEEE Journal of Lightwave Technologies. 2016. Vol. 34(2). PP. 582–592.

3. Sillard P., Molin D., Bigot-Astruc M., Amezcua-Correa A., de Jongh K., Achten F. 50 μm Multimode Fibers for Mode Division Multiplexing // IEEE Journal of Lightwave Technologies. 2016. Vol. 34(8). PP. 1672–1677.

4. Bottacchi S. Multi-Gigabit Transmission over Multimode Optical Fibre. Theory and Design Methods for 10gbe Systems. West Sussex: John Wiley & Sons Ltd. 2006.

5. Bunge C.-A., Choi S., Oh K. Analysis of Ring Launching Scheme Using Hollow Optical Fibre Mode Converter for 10 Gps Multimode Fibre Communication // Optical Fiber Technology. 2006. Vol. 12. PP. 48–58.

6. Sim D.H., Takushima Y., Chung Y.C. High-Speed Multimode Fiber Transmission by Using Mode-Field Matched CenterLaunching Technique // IEEE Journal of Lightwave Technology. 2009. Vol. 27(8). PP. 1018–1026.

7. Снайдер А., Лав Дж. Теория оптических волноводов: Пер. с англ. М.: Радио и связь, 1987. 656 с.

8. Bourdine A. Modeling and Simulation of Piecewise Regular Multimode Fiber Links Operating in a Few-Mode Regime // Advances in Optical Technologies. 2013. Vol. 2013. PP. 469389-1–469389-18.

9. Adams M.J. An Introduction to Optical Waveguides. New York: John Wiley and Sons. 1981.

10. Градштейн И.С., Рыжик И.М. Таблицы интегралов. М.: Физматгиз, 1962. 1100 с.

11. Bourdine A.V., Zhukov A.E. Fast Approximate Method for VCSEL-MMF Transverse Mode Coupling Analysis // Telecommunications and Radio Engineering. 2016. Vol. 7(11). PP. 979–999.

12. Бурдин А.В. Моделирование маломодовых оптических волокон с уменьшенной дифференциальной модовой задержкой в «С»-диапазоне длин волн // Труды учебных заведений связи. 2016. Т. 2. № 1. С. 32–37.

13. Андреев В.А., Бурдин А.В., Бурдин В.А., Дмитриев Е.В., Евтушенко А.С., Севрук Н.Л., Халиков Р.Х. Моделирование градиентного профиля показателя преломления кварцевых оптических волокон с диаметром сердцевины 42 мкм и уменьшенной дифференциальной модовой задержкой // Инфокоммуникационные технологии. 2016. № 3. С. 235–246.

14. Andreev V.A., Bourdine A.V., Burdin V.A., Evtushenko A.S., Halikov R.H. Design of Low DMD Few-Mode Optical Fibers with Extremely Enlarged Core Diameter Providing Nonlinearity Suppression for Operating Over “C”-Band Central Region // Proceedings of SPIE. 2016. Vol. 10342. PP. 1034207-1–1034207-8.

15. Dubois F., Emplit Ph., Hugon O. Selective Mode Excitation in Graded-Index Multimode Fiber by a Computer-Generated Optical Mask // Optics Letters. 1994. Vol. 19(7). PP. 433–435.

16. Karpeev S.V., Pavelyev V.S., Soifer V.A., Doskolovich L.L., Duparre M., Luedge B. Mode Multiplexing by Diffractive Optical Elements in Optical Telecommunication // Proceedings of SPIE. 2004. Vol. 5480. PP. 153–165.

17. Leon-Saval S.G., Argyros A., Bland-Hawthorn J. Photonic Lanterns: A Study of Light Propagation in Multimode to Single-Mode Converters // Optics Express. 2010. Vol. 18(8). PP. 8430–8439.