IMPLEMENTATION OF ATTENUATION IN FIBER OPTICAL DEVICES
Keywords:
Optical Devices, Fiber optic, Attenuation, Wavelength, Optical LinksAbstract
in the proposed work the implementation of different influencing factor of
attenuation in fiber optical devices has been presented. Absorption of optical energy by
tiny impurities in fibers such is iron, copper, or cobalt. Attenuation is a measure of the
loss of signal strength or light power that occurs as light pulses propagate through a run
of multimode or single-mode fiber. Measurements are typically defined in terms of
decibels or dB/km. The different size fibers have different optical loss dB/km values.
Fiber loss depends heavily on the operating wavelength. It has been simulated with
respect to distance, joints, and connectors. In the research work the attenuation in
different cases is calculated. Along with this the comparative analysis of attenuation is also provided in different
scenarios. In the future the research work would be beneficial.
References
Mehul G.Patel, S. B. Khant “Soliton Transmission in Fiber Optics for Long” 2014
Alla Abbas Khadir, Xiquan Fu and Baydaa F. Dhahir “Achieving Optical Fiber Communication Experiments by OptiSystem” 2014
Xue-zhao Zheng from China “A Measurement Method for Dispersion in Optical Fiber Communication with Long Distance”. 2014
S.K. Raghuwanshi, Vikram Palodiya, Ajay Kumar and Santosh Kumar “Experimental Characterization of Fiber Optic Communication Link for Digital Transmission System”
Hao Ziqiang, Li Hongzuo & Zhao Ting “Theoretical analysis on the transient characteristics of EDFA in optical fiber communication” discussed by was published. 2014
Francis Idachaba, Dike U. Ike, and Orovwode Hope “Future Trends in Fiber Optics Communication” 2014
Mohammed Yousef Al Gawagzeh & Amjad Hendi “Analysis of Opposing Stream Effect on the Non-uniform Optical Fiber Communication Lines”. 2012
Dr. K.A.Lathief “Attenuation Measurement in Optical Fiber Communication, 2014
Pulkit Berwal “Development in the Field of Optical Fiber Communication” 2013
J. Wen et al., “All-Fiber OAM Amplifier With High Purity and Broadband Spectrum Gain Based on Fused Taper Vortex-Beam Coupler,” IEEE Photonics J., vol. 10, no. 6, pp. 1–8, 2018.
X. Liu et al., “Fiber optic pressure and temperature monitoring system for downhole application,” ICOCN 2016 - 2016 15th Int. Conf. Opt. Commun. Networks, pp. 15–17, 2017.
J. Jiang et al., “Development of optical fiber temperature sensor for aviation industry,” ICOCN 2016 - 2016 15th Int. Conf. Opt. Commun. Networks, pp. 15–17, 2017.
D. Yang, D. Li, J. Tao, Y. Fang, X. Mao, and W. Tong, “An optical fiber comprehensive analysis system for spectral-Attenuation and geometry parameters measurement,” 2017 Conf. Lasers Electro-Optics Pacific Rim, CLEO-PR 2017, vol. 2017–January, pp. 1–2, 2017.
R. Kruglov, S. Loquai, C.-A. Bunge, O. Ziemann, B. Schmauss, and J. Vinogradov, “10 Gbit/s Short-Reach Transmission on 35 m Large-Core Graded-Index Polymer Optical Fiber,” Opt. Fiber Commun. Conf. Fiber Opt. Eng. Conf. 2011, p. OThZ6, 2011.
L. Ding, C. Xu, Z. Xia, B. Xu, and J. Huang, “Fiber optic sensor based on polarization-dependent absorption of graphene,” vol. 10323, p. 103237R, 2017.
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