Abstract
An upgraded 32 channel 256 Gbps dense wavelength division multiplexing-based radio over fiber optical scheme incorporating dispersion compensating fiber along with fiber Bragg grating as dispersion reparations is being simulated in OptiSystem software, transmitting data at the rate of 8 Giga bit per second per channel and receiving finest signal within 120 km. Four-wave mixing power level of side band is reduced by 6 and 7 dBm at 0 dBm and −10 dBm signal powers, respectively, which has been depicted in the spectrums achieved. The characteristics of transmission for long-distance traversal (120 km) along with channel gap of 100 GHz were observed to be superior compared to the existent wavelength division multiplexing—radio over fiber models. In this paper, we evaluate the effectiveness of the suggested system for 120 km transmission in 32-channel mode having 8 Giga bit per second per stream data rate at various feed in signal ranges of power (dBm), and find that the proposed system outperforms existing wavelength division multiplexing—radio over fiber structures, particularly in attenuating four-wave mixing sideband power. This paper in which the developed model has been analyzed in OptiSystem 17.0 software has offered enhanced transmission quality considering quality factor (Q-factor) and bit error rate (BER) at output side.
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References
Thomas VA, Ghafoor S, El-Hajjar M, Hanzo L (2013) A full-duplex diversity-assisted hybrid analogue/digitized radio over fibre for optical/wireless integration. IEEE Commun Lett 17(2):409–412
Tian F, Zhang P, Yan Z (2017) A survey on C-RAN security. IEEE Access 55:13372–13386
Sharma SR, Rana S (2017) Comprehensive study of radio over fiber with different modulation techniques—a review. Int J Comput Appl 170:22–25
Ilgaz MA, Baliz KV, Batagelj B (2020) A flexible approach to combating chromatic dispersion in a centralized 5G Network. Opto-Electron Rev 28:35–42
Kumar S, Yang D (2005) Second order theory for self-phase modulation and cross-phase modulation in optical fibers. J Lightwave Technol 23(6):2023
Forghieri F, Tkach R, Chraplyvy AR, Marcuse D (1994) Reduction of four-wave mixing crosstalk in WDM systems using unequally spaced channels. IEEE Photon Technol Lett 6(6):754–756
Betti S, Giaconi M, Nardini M (2003) Effect of four-wave mixing on WDM optical systems: a statistical analysis. IEEE Photon Technol Lett 15(8):1079–1081
Patnaik B, Sahu P (2010) Optimization of four wave mixing effect in radio-over-fiber for a 32-channel 40-gbps dwdm system. In: 2010 International symposium on electronic system design (ISED). IEEE, pp 119–124
Kathpal N, Kumar Garg A (2020) Analysis of radio over fiber system for mitigating four-wave mixing effect. Digital Commun Netw 6(1):115–122
Bhattacharjee R, Dey P, Saha A (2020) An efficient DFG induced wavelength exchanged-OPC using only two Ti:PPLN waveguides with single pump configuration. Optik 202:163704
Bhattacharjee R, Dey P, Saha A (2020) An improved hybrid OTDM-WDM transmission system for effective nonlinearity mitigation utilizing Ti:PPLN waveguide based OPC module. Optik 219:165241
Bhattacharjee R, Dey P, Saha A (2022) Implementation of an enhanced 32 channel 256 Gbps DWDM based radio over fiber optical system for constricted channel spacing employing Fiber Bragg Grating. Optik 253:168598
Xu T, Shevchenko NA, Lavery D, Semrau D, Liga G, Alvarado A, Killey RI, Bayvel P (2017) Modulation format dependence of digital nonlinearity compensation performance in optical fibre communication systems. Opt Express 25:3311–3326
Bakhshali A, Chan WY, Cartledge JC, O’Sullivan MC, Laperle C, Borowiec A, Roberts K (2016) Frequency-domain Volterra-based equalization structures for efficient mitigation of intrachannel Kerr nonlinearities. J Light Technol 34:1770–1777
Liu X, Chraplyvy A, Winzer P, Tkach R, Chandrasekhar S (2013) Phase-conjugated twin waves for communication beyond the Kerr nonlinearity limit. Nat Photonics 7:560
Ke JH, Gao Y, Cartledge JC, Hasegawa T, Yamamoto Y, Hirano M (2017) 400 Gbit/s optimal fiber design for large capacity long haul coherent transmission. Opt Express 25:706–712
Dong-Nhat N, Elsherif MA, Minh HL, Malekmohammadi A (2017) NRZ versus RZ over absolute added correlative coding in optical metro-access networks. Opt Commun 387:30–36
Bhatia R, Sharma AK, Saxena J (2016) Improved analysis of four wave mixing with sub-plank higher-order dispersion parameters in optical communication systems. Optik 127(8):9474
Ferreira MF (2011) Nonlinear effects in optical fibers, 2nd edn. Wiley
Azaña J (2010) Ultrafast analog all-optical signal processors based on Fiber-Grating devices. IEEE Photonics J 2:359–386
Chien C, Lyubomirsky I (2007) Comparison of RZ versus NRZ pulse shapes for optical duobinary transmission. J Lightwave Technol 25:2953–2958
Sharma A, Singh I, Bhattacharya S, Sharma S (2019) Performance comparison of DCF and FBG as dispersion compensation techniques at 100 Gbps over 120 km using SMF. In: Proceeding of NCCS 2017. Nanoelectronics, Circuits and Communication Systems, Singapore, pp 435–449
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Dey, P., Goswami, P.R., Bhattacharjee, R., Kar, A., Saha, A. (2023). Evaluation of Radio Over Fiber Optical System Supported by Fiber Bragg Grating and Dispersion Compensating Fiber for Attenuating Four-Wave Mixing Effect. In: Kumar, S., Hiranwal, S., Purohit, S.D., Prasad, M. (eds) Proceedings of International Conference on Communication and Computational Technologies . Algorithms for Intelligent Systems. Springer, Singapore. https://doi.org/10.1007/978-981-19-3951-8_43
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DOI: https://doi.org/10.1007/978-981-19-3951-8_43
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