Wavelength effect in 100Gbit/s WDM transmission in a telecommunication network

• Autorzy: Tebbal El hadj atif , Hasni Abdelhafid

Identyfikatory

DOI

10.15199/48.2023.03.49

Warianty tytułu

PL

Efekt długości fali w transmisji WDM 100Gbit/s w sieci telekomunikacyjnej

• Języki publikacji: EN

Abstrakty

EN

These Optical transport networks are today the basic infrastructure of modern communications systems for the transfer of data between nodes. This paper proposes a transparent optical architecture for metropolitan area networks. This multi-service architecture allows supporting both 100Gbit/s WDM-PON transmission system and the wavelength raport to offers a performance suitable for this network architecture. we consider architecture based on the combined use of optical link and increase bit rate with wavelength associate. the simulation of this study was used by optisystem, the system is composed of 100Gbits with 100Km optical fiber length based on the different input design parameters such as input signal power, optical fiber length and attenuation coefficient. The results are discussed in terms of quality factor (Q-factor) and eye diagram.

PL

Te optyczne sieci transportowe są dziś podstawową infrastrukturą nowoczesnych systemów komunikacyjnych do przesyłania danych między węzłami. W artykule zaproponowano przezroczystą architekturę optyczną dla sieci metropolitalnych. Ta wielousługowa architektura pozwala na obsługę zarówno systemu transmisji 100Gbit/s WDM-PON jak i raportu długości fali, oferując wydajność odpowiednią dla tej architektury sieci. rozważamy architekturę opartą na łącznym wykorzystaniu łącza optycznego i zwiększeniu przepływności wraz ze skojarzeniem długości fali. Symulacja tego badania została wykorzystana przez optisystem, system składa się z 100Gbits o długości światłowodu 100Km w oparciu o różne parametry wejściowe projektu, takie jak moc sygnału wejściowego, długość światłowodu i współczynnik tłumienia. Wyniki omówiono pod kątem współczynnika jakości (Q-factor) i wykresu oka.

Słowa kluczowe

EN

optical fibre; WDM; ROADM; Q-Factor; BER

PL

światłowód; WDM; ROADM; Q-Factor; BER

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2023
• Tom: R. 99, nr 3
• Strony: 277--283
• Opis fizyczny: Bibliogr. 26 poz., rys., tab.

Twórcy

autor

Tebbal El hadj atif

• University of Tahri Mohammed Bechar Algerie

autor

Hasni Abdelhafid

• University of Tahri Mohammed Bechar Algerie

Bibliografia

• [1] Ali A. And Hammadi A. M, Dispersion compensation of optical systems utilizing fiber Bragg grating at 15 Gbits/s, IJEECS. Indonesian J Elec Eng &Comp Sci., 22(2021), No. 1, 369–378
• [2] Queseth O, Bulakci Ö, Spapis P, Bisson P, Marsch P, Arnold P, Rost P, Wang Q, Blom R, Salsano S, Chen, T, Buda T, Frascolla, V., Li, X., & Yousaf, Z, View on 5G architecture: European Commission, Version (2.0), pp.140, Dec 2017.
• [3] Kumar S and JamalDeen M, Channel Multiplexing Techniques , in Fiber Optic Communications, John Wiley & Sons, Ltd first edition, Set in 10/12pt TimesLTStd by Laserwords Private Limited, Chennai, (2014).
• [4] ADARDOUR H. E, KAMECHE S, Étude et Conception d‟un Système de Transmission WDM 4 x 20 Gbit/s,, in The International Conference on WIreless Technologies embedded and intelligent Systems, ENSA of Kenitra, (2016), 259–263.
• [5] Ali A. H, Alhamdane H. J, and Hassen B. S, Design analysis and performance evaluation of the WDM integration with COOFDM system for radio over fiber system, IJEECS. Indonesian J Elec Eng &Comp Sci, 15(2019), No. 2, 870–878
• [6] Kawakami H, Yoshida E, Hubota H and Miyamoto Y, Nouvelle technique de surveillance de la dispersion chromatique signée basée sur la distorsion de forme d'onde asymétrique dans le récepteur DQPSK, Joint Conference of the Opto-Electronics and Communications Conference and the Australian Conference on Optical Fibre Technology OECC/ACOFT of Sydney 'NSW, Australia (2008), 1-2
• [7] Kozicki B, Maruta A, and Kitayama K, Experimental investigation of delay-tap sampling technique for online monitoring of RZ-DQPSK Signals, IEEE Photonics Technology Letters, 21(2009), No. 3, 179–181
• [8] Zhaohui L, Zhao J, Linghao C, Yanfu Y, Chao L, Alan P, Tao L, Changyuan Y, HY T and PKA W. K and Singh M, Signed chromatic dispersion monotoring of 100Gbit/s CS-RZ DQPSK signal by evaluating the asymmetry radio of delay tap sampling,Optics Express.OE, 18(2010), No.3, 3149–3157
• [9] Li L, Jin-Ling C, and Ji-jun Z, research of 100Gbit/s DPQPSK based on DSP in WDM-PON system, International Journal of Signal Processing, Image Processing and Pattern Recognition, 8(2015), No.3, 121–130
• [10] Hara K, Nakamura H, Kimura S, Yoshino M, Nishihara S, Flexible load balancing technique using dynamic wavelength bandwidth allocation (DWBA) toward 100Gbit/s-class WDM/TDM-PON, 36th European Conference and Exhibition on Optical Communication, ECOC (Torino, Italy), (2010), 978–980
• [11] BARAKETI S, Ingénierie des réseaux optiques SDH et WDM et étude multicouche IP/MPLS sur OTN sur DWDM, Doctoral thesis, Dept. EDSYS , Univ Toulouse 3 Paul Sabatier (UT3 Paul Sabatier), Toulouse, France, (2015).
• [12] MENIF M, Etudes des Comportements des Amplificateurs Optiques Fibre face a un traffic auto similaire, Doctoral thesis, Dept. Génie Électrique et de Génie Informatique, Univ Sherbrooke, Québec, Canada, (2014)
• [13] Ali H, Kadhim S. A, Kazr K. A, Lateef A. T, Simulation and Performance Analysis of a Fiber Communication System based on FBG as Dispersion Compensator, International Journal of New Technology and Research (IJNTR), 4(2018), 62-66
• [14] Zangh J, Jia Z, Coherent Passive Optical Networks for 100G/λ-and-Beyond Fiber Access: Recent Progress and Outlook, IEEE Network, 36(2022), 116–123
• [15] Shieh W, PMD-Supported Coherent Optical OFDM Systems, IEEE Photonics Technologie Letters, 19(2007), No. 3, 134–136
• [16] Aso O, Tadakuma M, and Namiki S, Four-Wave Mixing in Optical Fibers and Its Applications, Furukawa Review, 19(2000), 63–68
• [17] Kumar S, Yang D, Second-Order Theory for Self-Phase Modulation and Cross-Phase Modulation in Optical Fibers, Journal of Lightwave Technology, 23(2005), No. 6, 2073–2077
• [18] Rasztovits-Wiech M, Danner M., and Leeb W. R, Optical signal-tonoise ratio measurement in WDM networks using polarization extinction, in ECOC 98, (1998), 549–550
• [19] Lee J. H, Jung D. K, Kim C. H, and Chung Y. C, OSNR monitoring technique using polarization -nulling method, IEEE PHOTONICS TECHNOLOGY LETTERS, 13(2021), No. 1, 88–90
• [20] Moench W, Loecklin E, Measurement of Optical Signal-to-Noise-Ratio in Coherent Systems using Polarization Multiplexed Transmission, Optical Fiber Communication Conference,OSA Technical Digest Th2A, 42 (2017), 19-23
• [21] Gariepy D, Searcy S, He G, Tibuleac S, Non-intrusive OSNR measurement of polarization-multiplexed signals with spectral shaping and subject to fiber non-linearity with minimum channelspacing of 37.5GHz, OPTICS EXPRESS 20156, 24(2016), No.18, 20156–20166,
• [22] Dong Z, Khan F. N, Sui Q., Zhong K, Lu C., and Lau A. P. T, Optical performance monitoring: A review of current and future technologies, J. Lightwave Technol. 34(2016), No.2, 525–543.
• [23] Perényi M, Zsigmond S. and Cinkler T, ILP formulation of signal power based routing for single and multilayer opticalnetworks, 5th International Conference on Broadband Communications, Networks and Systems, London, UK, (2008), 08-11
• [24] Tomkos I, Vogiatzis D, Mas C, Zacharopoulos l, Tzanakaki A, and Varvarigos E, Performance Engineering of Metropolitan Area Optical Networks through Impairment Constraint Routing, IEEE Optical Communications, 42(2004), No.8, 540–547
• [25] Cinkler T., Configuration and Re-Configuration of WDM networks, NOC’98, European Conference on Networks and Optical Communications Arie M.C.A Koster, X.MUNOZ. Editor, Manchester UK, 1998, pp.28-90.
• [26] Deore A, Turkcu O, Ahuja S., Hand J., and Melle S., Corporation, Total Cost of Ownership of WDM and Switching Architectures for Next-Generation 100Gb/s Networks, IEEE Communications Magazine, 50(2012), 179-187.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).