Investigation of an Information Leakage Channel in the Area of Optical Fiber Bending

An information leakage channel created on the basis of fiber bending when transmitting information over an optical fiber is studied. An increase in the bending diameter of an optical fiber is shown to lead to a decrease in the power of optical radiation proceeding from it. In a bending diameter range from 5 to 20 mm, the highest radiation power was observed for the optical fiber G.655, while the lowest corresponding figure was recorded for G.657. The information leakage channel bandwidth with changed bending diameter is determined for different types of optical fiber. The bandwidth of the information leakage channel is shown to depend on the location of the photodetector used to register optical radiation taken from the bend of the optical fiber.

1. Govind P. Agrawal Fiber-Optic Communication Systems. New York: Wiley-Interscience; 2002. 530 p.

2. Dmitriev S.A., Slepov N.N. Fiber-Optic Technology: Current State and New Prospects. Moscow: Tekhnosfera Publ.; 2010. 576 p. (in Russ.)

3. Ubaydullaev R.R. Fiber-Optic Networks. Moscow: Eco-Trends Publ.; 2001. 263 p. (in Russ.)

4. Zenevich A.O. Detectors of Information Leakage from Optical Fiber. Minsk: Belarusian State Academy of Communications Publ.; 2017. 143 p. (in Russ.)

5. Unger G. Optical Communication. Moscow: Svyaz' Publ.; 1979. 264 p. (in Russ.)

6. Shubin V.V. Information Security of Fiber-Optic Systems. Sarov: Russian Federal Nuclear Center – All-Russian Scientific Research Institute of Experimental Physics Publ.; 2015. 257 p. (in Russ.)

7. Iqbal M.Z., Fathallah H., Belhadj N. Optical fiber tapping: Methods and precautions. Proceedings of the 8th International Conference on High-capacity Optical Networks and Emerging Technologies, 19−21 December 2011, Riyadh, Saudi Arabia. IEEE; 2011. p.164−168. DOI:10.1109/HONET.2011.6149809

8. Baranochnikov M.L. Infrared Radiation Receivers. The State of Development and Industrial Output, Development Prospects and Forecasts. Analytical Review. Moscow: 1985. 94 p. (in Russ.)

9. Listvin A.V., Listvin V.N., Shvyrkov D.V. Optical Fibers for Communication Lines. Moscow: LESA Rart Publ.; 2003. 107 p. (in Russ.)

10. Gulakov I.R., Zenevich A.O., Kochergina O.V., Matkovskaia T.A. Study of the characteristics of germanium avalanche photodiodes in the photon counting mode. Proceedings of the National Academy of Sciences of Belarus, Physical-Technical Series. 2022;67(2):228−235. DOI:10.29235/1561-8358-2022-67-2-222-229

11. GOST R 52266−2020 Fibre optical cables. General specifications. Moscow: Standartinform Publ.; 2020. (in Russ.)

12. GOST R 17772−88 Semiconducting photoelectric detectors and receiving photoelectric devices. Methods of measuring photoelectric parameters and determining characteristics. Moscow: Izdatel'stvo standartov Publ.; 1988. 64 p. (in Russ.)

13. Rec. ITU-T G652 (11/2016) Characteristics of single-mode optical fiber and cable.

14. Rec. ITU-T G657 (11/2016) Characteristics of a bending loss insensitive single mode optical fibre and cable for the access network.