Home Design and implementation of OLT switching function in 40/10G TDM-PON experimental system
Article
Licensed
Unlicensed Requires Authentication

Design and implementation of OLT switching function in 40/10G TDM-PON experimental system

  • Juntao Han EMAIL logo , Rongchuan Yang and Chaosheng Tang
Published/Copyright: July 16, 2021
Become an author with De Gruyter Brill
Submit Manuscript Author Information
Journal of Optical Communications
From the journal Journal of Optical Communications Volume 44 Issue 4

Abstract

The access network is developing towards large capacity, wide-coverage, and low delay, which puts forward higher requirements for network structure and data exchange performance of optical access network equipment. In this paper, we have designed a high-speed optical network device with 40/10G TDM-PON. To effectively solve the problem of network switching capability in high-speed data transmission, we propose a low delay large capacity switching algorithm, which minimizes the network switching delay. We model the network by integer linear programming and simulate the network based on OMNeT++. The simulation results show that the algorithm can effectively solve the problem of network switching delay in the high-speed network environment.

Keywords: 40/10G; access network; high-speed; optical network; TDM-PON
Corresponding author: Juntao Han, School of E-Commerce and Logistics Management, Henan University of Economics and Law, Zhengzhou, Henan, 450046, P.R. China, E-mail:

  1. Author contributions: All the authors have accepted responsibility for the entire content of this submitted manuscript and approved submission.

  2. Research funding: None declared.

  3. Conflict of interest statement: The authors declare no conflicts of interest regarding this article.

References

1. Graham, DJ, Drury, DM, Helmsen, EJ. System architecture for an optical switch using wavelength, fiber and polarizaton addressing. J Lightwave Technol 2014;2:25–7.Search in Google Scholar

2. ONF White Paper. Software-defined networking: the new norm for networks. Open Network Foundation (ONF); 2012:3–5 pp.Search in Google Scholar

3. Sadikov, GG, Antsyshkina, AS, Sergienko, VS. The structure of the scandium iodide complex with antipyrine (AP) and its comparison with the structure of nonisostructural analogues. Crystallogr Rep 2009;54:841–5. https://doi.org/10.1134/s1063774509050162.Search in Google Scholar

4. Wang, YQ, Chu, C. Snitrosylation control of ROS and RNS homeostasis in plants: the switching function of catalase. Mol Plant 2020;13:946–8. https://doi.org/10.1016/j.molp.2020.05.013.Search in Google Scholar PubMed

5. Luo, YQ, Zhou, XP, Effenberger, F, Yan, X, Peng, G, Qian, Y, et al.. Time and wavelength division multiplexed passive optical network (TWDM-PON) for next-generation PON Stage2 (NG-PON2). J Lightwave Technol 2013;31:587–93. https://doi.org/10.1109/jlt.2012.2215841.Search in Google Scholar

6. Yoshima, S, Nakagawa, N, Nakagawa, J, Kitayama, K. 10G-TDM-OCDMA-PON systems. In: OECC 2010 technical digest, Sapporo, Japan. IEEE; 2010:724–25 pp.Search in Google Scholar

7. ITU-T, Rec I.G.709/Y.1331. Interfaces for the optical transport network (OTN); 2012:5–8 pp.Search in Google Scholar

8. Soto, AI, Soto, WG. System and method for optical layer management in optical modules and remote control of optical modules. Commun Mag IEEE 2012;40:66–73.Search in Google Scholar

9. Kastner, J, Schnabel, U. Device with ethernet switch function and single ethernet connector. J Opt Netw 2009;4:537–8.Search in Google Scholar

10. Saliou, F, Chanclou, P, Genay, N, Lazaro, JA, Bonada, F, Othmani, A, et al.. Single SOA to extend simultaneously the optical budget of coexisting G-PON and 10G-PON. In: 36th European conference and exhibition on optical communication, Torino, Italy. IEEE; 2010:10–3 pp.10.1109/ECOC.2010.5621225Search in Google Scholar

11. Ming, J, Zhang, DZ. Utilizing 10G PON to construct optical access highway. Telecommunications Network Technology; 2016:11–5 pp.Search in Google Scholar

12. Meng, X, Yu, H, Wu, H, Xu, T. Research on the smooth switching control strategy for the four-tank liquid level system. In: 2019 Chinese automation congress (CAC), Hangzhou. IEEE; 2020:5187–93 pp.10.1109/CAC48633.2019.8997393Search in Google Scholar

13. Wang, X, Wang, L, Xue, C, Yan, H, Qin, P. Experimental demonstration of 40G multiplexing and demultiplexing functions for the 40g/10g TDM-PON experimental system. In: 2014 Asia communications and photonics conference (ACP), Shanghai, China. IEEE; 2019:86–90 pp.10.1364/ACPC.2014.ATh3A.126Search in Google Scholar

14. Lu, G, Liu, Z, Zhou, Z. Multicast routing based on ant algorithm for delay-bounded and load-balancing traffic. In: Proceedings 25th annual IEEE conference on local computer networks, Tampa, FL, USA. IEEE; 2000:362–68 pp.Search in Google Scholar

15. Tzeng, SJ. Time synchronization architecture in a network device. Chin Laser 2015:1777–83.Search in Google Scholar

16. Carey, D, Brandonisio, N, Porto, S, Naughton, A, Ossieur, P, Parsons, N, et al.. Dynamically reconfigurable TDM-DWDM PON ring architecture for efficient rural deployment. In: ECOC 2016, 42nd European conference on optical communication, Dusseldorf, Germany. VDE; 2016:178–83 pp.Search in Google Scholar

17. Sharma, R, Dewra, S, Rani, A. Performance analysis of hybrid PON (WDM-TDM) with equal and unequal channel spacing. J Opt Commun 2016;37:247–52. https://doi.org/10.1515/joc-2015-0055.Search in Google Scholar

18. Koma, R, Fujiwara, M, Kani, JI, Suzuki, KI, Otaka, A. B-8-36 a study on wide dynamic range reception of TDM-based digital coherent PON upstream using automatic gain controlled optical amplifier. In: Society conference of IEICE 2015. The Institute of Electronics, Information and Communication Engineers; 2015, 21:223–8 pp.Search in Google Scholar

19. Narayanasamy, S, Pulla, IR. Virtual machine and application movement over a wide area network. J Opt Netw 2014;4:117–9.Search in Google Scholar

20. Sakaue, Y, Asaka, K, Senoo, Y, Kaneko, S, Yoshida, T, Sugawa, J, et al.. Optical path protection with FEC switching in WDM/TDM-PON for ring access networks. In: European conference on optical communication, Valencia, Spain. IEEE; 2015:221–9 pp.10.1109/ECOC.2015.7341817Search in Google Scholar

21. Ma, J, Qin, P, Wang, L, Xue, C. The overall design and implementation of embedded software for 40/10g TDM-PON. In: 2014 Asia communications and photonics conference (ACP), Shanghai, China. IEEE; 2019:98–102 pp.10.1364/ACPC.2014.ATh3A.173Search in Google Scholar

22. Shoemaker, K, Wagh, M, Han, W, Athreya, M, Mandhani, A, Thakkar, S. Providing a peripheral component interconnect (PCI)-compatible transaction level protocol for a system on a chip (SoC). Opt Soc Am 2014;Th5A. 4.Search in Google Scholar

23. Avery, JM. Method and apparatus for implementing PCI DMA speculative prefetching in a message passing queue oriented bus system. Opt Soc Am 2014:Th5A. 24.Search in Google Scholar

24. Roundtree, B, Allan, K, Beinikis, L, Rush, K. Call intercept methods, such as for customer self-support on a mobile device. J Lightwave Technol 2017;31:47–50.Search in Google Scholar

25. Chen, LP, Xu, Z. The design and implementation of on board data handling system based on VxWorks. In: Proceedings of 2015 international workshop on wireless communication and network (IWWCN2015), Kunming, China. Wireless Communication and Network; 2016:12–5 pp.10.1142/9789814733663_0054Search in Google Scholar

26. Wu, Y, Zheng, Y, Song, X, Zang, Z, Liu, Y. Research on the power information collector of optical fiber based on EPON technology. In: 2013 15th international conference on advanced communications technology (ICACT), PyeongChang, Korea (South). IEEE; 2013:122–27 pp.Search in Google Scholar

27. Yan, FX, Niu, ZJ, Du, SW, Pan, TL. Qt-based C/C++ development pattern and its application for android APP. Comput Syst Appl 2018;27:96–102.Search in Google Scholar

28. Roslyakov, AV. Analysis of energy consumption in the TDM-PON. In: Conference on Optical Technologies in Telecommunications. Samara, Russia: Povolzhskiy State University of Telecommunications and Informatics; 2017:77–82 pp.Search in Google Scholar

29. Grobr, K. Next-generation access/backhaul based on ITU G. 898, NG-PON2. In: Photonic networks; 15. ITG Syposium, Leipzig, Germany. VDE; 2014, 5:99–104 pp.Search in Google Scholar

30. Mohammed, A, Newaz, S, Al-Hazemi, F, Choi, J. Grant management procedure for energy saving TDM-PONs. Opt Fiber Technol 2018;40:118–29.10.1016/j.yofte.2017.11.014Search in Google Scholar
Received: 2021-02-20
Accepted: 2021-06-19
Published Online: 2021-07-16
Published in Print: 2023-10-26

© 2021 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Amplifiers
  3. Effect of carrier (hole) temperature on performance of optical amplifiers quantum dot structure
  4. Devices
  5. 1 × 2 power splitter based on photonics crystals fibers
  6. Evolution of Adder and Subtractor Circuit Using Si3N4 Microring Resonator
  7. Fibers
  8. Different Photonic Crystal Fibers Configurations with the Key Solutions for the Optimization of Data Rates Transmission
  9. Networks
  10. Design and implementation of OLT switching function in 40/10G TDM-PON experimental system
  11. A parallel cross-connection recovery scheme for dual link failure in elastic optical networks
  12. A Brief Review on the Methods that Improve Optical Burst Switching Network Performance
  13. MBO-Based Bandwidth Allocation and Traffic Coloring Optimization in PON
  14. HMM-Based Secure Framework for Optical Fog Devices in the Optical Fog/Cloud Network
  15. Attack-Aware Dynamic Upstream Bandwidth Assignment Scheme for Passive Optical Network
  16. Systems
  17. 2 × 10 Gbit/s–10 GHz Radio over Free Space Optics Transmission System Incorporating Mode Division Multiplexing of Hermite Gaussian Modes
  18. Impact of Rayleigh-Distributed PAPR on the Performance of a Pre-Clipped DCO-OFDM System
  19. Suitability of FBG for Gain Flatness of 64 × 10 Gbps DWDM System Using Hybrid (EDFA+YDFA) Optical Amplifier in C + L Band up to 50 GHz (0.4 nm) Channel Spacing
  20. BER Performance Analysis of an Orthogonal FDM Free Space Optical Communication System with Homodyne Optical Receiver over Turbulent Atmospheric Channel
  21. Theory
  22. Numerical Analysis of Soliton Propagation in a Tapered Waveguide
  23. New Optical Codes Based on Construction of Parity Check Matrix of LDPC Codes
  24. Performance Analysis of 20 Gbit/s–40 GHz MDM-Ro-FSO Link Incorporating DPSK Modulation Scheme
https://doi.org/10.1515/joc-2021-0052
Keywords for this article
40/10G; access network; high-speed; optical network; TDM-PON

Articles in the same Issue

  1. Frontmatter
  2. Amplifiers
  3. Effect of carrier (hole) temperature on performance of optical amplifiers quantum dot structure
  4. Devices
  5. 1 × 2 power splitter based on photonics crystals fibers
  6. Evolution of Adder and Subtractor Circuit Using Si3N4 Microring Resonator
  7. Fibers
  8. Different Photonic Crystal Fibers Configurations with the Key Solutions for the Optimization of Data Rates Transmission
  9. Networks
  10. Design and implementation of OLT switching function in 40/10G TDM-PON experimental system
  11. A parallel cross-connection recovery scheme for dual link failure in elastic optical networks
  12. A Brief Review on the Methods that Improve Optical Burst Switching Network Performance
  13. MBO-Based Bandwidth Allocation and Traffic Coloring Optimization in PON
  14. HMM-Based Secure Framework for Optical Fog Devices in the Optical Fog/Cloud Network
  15. Attack-Aware Dynamic Upstream Bandwidth Assignment Scheme for Passive Optical Network
  16. Systems
  17. 2 × 10 Gbit/s–10 GHz Radio over Free Space Optics Transmission System Incorporating Mode Division Multiplexing of Hermite Gaussian Modes
  18. Impact of Rayleigh-Distributed PAPR on the Performance of a Pre-Clipped DCO-OFDM System
  19. Suitability of FBG for Gain Flatness of 64 × 10 Gbps DWDM System Using Hybrid (EDFA+YDFA) Optical Amplifier in C + L Band up to 50 GHz (0.4 nm) Channel Spacing
  20. BER Performance Analysis of an Orthogonal FDM Free Space Optical Communication System with Homodyne Optical Receiver over Turbulent Atmospheric Channel
  21. Theory
  22. Numerical Analysis of Soliton Propagation in a Tapered Waveguide
  23. New Optical Codes Based on Construction of Parity Check Matrix of LDPC Codes
  24. Performance Analysis of 20 Gbit/s–40 GHz MDM-Ro-FSO Link Incorporating DPSK Modulation Scheme
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 29.10.2025 from https://www.degruyterbrill.com/document/doi/10.1515/joc-2021-0052/html
Scroll to top button