Home PIIN Cancellation Using a Novel Receiving Architecture for Spectral/Spatial SAC-OCDMA System
Article
Licensed
Unlicensed Requires Authentication

PIIN Cancellation Using a Novel Receiving Architecture for Spectral/Spatial SAC-OCDMA System

  • A. Bouarfa EMAIL logo , M. Kandouci , A. Garadi and H. Djellab
Published/Copyright: December 15, 2017
Become an author with De Gruyter Brill
Submit Manuscript Author Information
Journal of Optical Communications
From the journal Journal of Optical Communications Volume 41 Issue 3

Abstract

Increasing the number of users presents a limitation in one-dimensional (1D) spectral amplitude coding (SAC) for Optical Code Division Multiple Access (OCDMA) system. In order to overcome this disadvantage, a new architecture of the two-dimensional wavelength/spatial SAC-OCDMA system using the multi-diagonal (MD) code has been proposed. The 2D-MD code possesses the same properties of 1D-MD code, which leads to total suppression of the multiple access interference. Unlike conventional receivers used in precedent studies, where the phase-induced intensity noise (PIIN) is a drawback, the suggested structure not only eliminates PIIN but reduces the system architecture. The results show that the user’s number reached by the proposed system is the user number’s multiplication of the 1D system and the couplers’ number. Moreover, the new 2D-MD system presents good performances at the high data rate.

Keywords: multi diagonal code; optical code division multiple access; modified direct detection; phase induced intensity noise

References

1. Yin H, Richardson DJ. Optical code division multiple access communication networks: theory and applications. Beijing: Tsinghua University Press, 2007.Search in Google Scholar

2. Ghafouri-Shiraz H, Karbassian MM. Optical CDMA networks: principles, analysis and applications. New York, NY: Wiley-IEEE Press, 2012.10.1002/9781119941330Search in Google Scholar

3. Karbassian MM, Ghafouri-Shiraz H. Optical CDMA transceiver architecture: polarization modulation with dual-balanced detection. In: Gelman L, Ao SI, editors. Advances in electrical engineering and computational science. Springer, Netherlands, 2009:47–57. ISBN: 978-90-481-2310-0.10.1007/978-90-481-2311-7_5Search in Google Scholar

4. Morelle M, Goursaud C, Julien-Vergonjanne A, Aupetit-Berthelemot C, Cances JP, Dumas JM. 2-dimensionnal code design for an optical cdma system with a parallel interference cancellation receiver. Eur Trans Telecommun. 2007;18:761–8.10.1002/ett.1165Search in Google Scholar

5. Yang GC, Kwong WC. Prime codes with applications to CDMA optical and wireless networks. Norwood, MA: Artech House, 2002.Search in Google Scholar

6. Yang CC, Huang JF. Two-dimensional M-matrices coding in spatial/frequency optical CDMA networks [J]. IEEE Photon Technol Lett. 2003 Feb;15(1):168–70.10.1109/LPT.2002.805780Search in Google Scholar

7. Tsai CM. Optical wavelength/spatial coding system based on quadratic congruence code matrices. IEEE Photon Technol Lett. 1843–1845;18:2006.10.1109/LPT.2006.881210Search in Google Scholar

8. Yang CC, Huang JF, Chiu IM. Performance analyses on hybrid MQC/M-sequence coding over frequency/spatial optical CDMA system. IEEE Trans Commun. 2007;55:40–3.10.1109/TCOMM.2006.887793Search in Google Scholar

9. Yeh BC, Lin CH, Yang CL, Wu J. Noncoherent spectral/spatial optical CDMA system using 2-D diluted perfect difference codes. J Light Wave Technol. 2009;27(13):2420–28.10.1109/JLT.2008.2010721Search in Google Scholar

10. Kadhim RA, Fadhil HA, Aljunid SA, Razalli MS. A new two dimensional spectral/spatial multidiagonal code fornoncoherent optical code division multiple access (OCDMA) systems. Opt Commun. 2014;329:28–33.10.1016/j.optcom.2014.04.082Search in Google Scholar

11. Norazimah MZ, Aljunid SA, Fadhil HA, Md Zain AS. Analytical comparison of various SAC-OCDMA detections techniques. In: IEEE 2 International Conference on Photonics (ICP 2011), art. no. 6106864. 2011:167–71.10.1109/ICP.2011.6106864Search in Google Scholar

12. Sahbudin RK, Abdullah MK, Mokhtar M. Performance improvement of hybrid subcarrier multiplexing optical spectrum code division multiplexing system using spectral direct decoding detection technique. J Opt Fiber Technol Elsevier. 2009;15:266–73.10.1016/j.yofte.2008.12.003Search in Google Scholar

13. Hasoon FN, Al-Mansoori MH, Shaari S. Different detection schemes using enhanced double weight code for OCDMA systems. In: Yang GC, Ao S, Gelman L, editors. IAENG transactions on engineering technologies. Lecture notes in electrical engineering, vol. 229. Dordrecht: Springer, 2013.Search in Google Scholar

14. Rashidi CB, Anuar MS, Aljunid SA. Study of direct detection technique for zero cross correlation code in OCDMA. In: Proc international conference on computer and communication engineering. 11–13 May 2010, Kuala Lumpur, Malaysia.10.1109/ICCCE.2010.5556830Search in Google Scholar

15. Garadi A, Djebbari A, Abdelmalik TA. Exact analysis of signal-to-noise ratio for SAC-OCDMA system with direct detection. Optik Int J Light Opt. 2017;145:89–94. DOI:10.1016/j.ijleo.2017.07.038Search in Google Scholar

16. Abd TH, Aljunid SA, Fadhil HA, Ahmad RA, Saad NM. Development of a new code family based on SAC-OCDMA system with large cardinality for OCDMA network. Opt Fiber Technol. 2011 May;17:273–80.10.1016/j.yofte.2011.04.002Search in Google Scholar

17. Jellali N, Najjar M, Ferchichi M, Rezig H. Three-dimensional multi-diagonal codes for OCDMA system. Optik Int J Light Opt. 2017;145: 428–35. ISSN 0030-4026.10.1016/j.ijleo.2017.07.057Search in Google Scholar

18. Abd TH, Aljunid SA, Fadhil HA, Junita MN, Saad NM. Modelling and simulation of a 1.6 Tb/s optical system based on multi-diagonal code and optical code-division multiple access. Ukr J Phys Opt. 2012;13(2):54–66.10.3116/16091833/13/2/54/2012Search in Google Scholar

19. Bouarfa A, Kandouci M. Performance of spectral amplitude coding OCDMA using multi-identity high power code. J Adv Comput Networks. 2016;4(4):184–88.Search in Google Scholar

20. Fadhil HA, Aljunid SA, Ahmed RB. Effect of random diagonal code link of an OCDMA scheme for high-speed access networks. J. Opt Fiber Technol. 2009 June;15:237–41.10.1016/j.yofte.2008.11.001Search in Google Scholar

21. Rashidi CB, Anuar MS, Aljunid SA. Study of direct detection technique for zero cross correlation code in OCDMA.” In: International Conference on Computer and Communication Engineering (ICCCE 2010), 11–13 May 2010, Kuala Lumpur, Malaysia.10.1109/ICCCE.2010.5556830Search in Google Scholar

22. Imtiaz WA, Ahmad N. Cardinality enhancement of SAC-OCDMA systems using new diagonal double weight code. Int J Commun Networks Inf Security (IJCNIS). 2014;6:226.10.17762/ijcnis.v6i3.852Search in Google Scholar

Received: 2017-10-16
Accepted: 2017-12-07
Published Online: 2017-12-15
Published in Print: 2020-04-28

© 2020 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Amplifiers
  3. Automatic Gain-Controlled HOA with Residual Pumping
  4. Performance Evaluation of DPSK System with Different Combination of Hybrid Optical Amplifiers by Using Equal and Unequal Channel Spacing
  5. Devices
  6. Investigation of Photonic Integrated Circuits with Low-Loss Bragg Gratings
  7. Design and Performance Analysis of MZI Based 2×2 Reversible XNOR Logic Gate
  8. Design and Numerical Analysis of an All-optical 4-channel Power Splitter in E, S, C, L, and U Bands via Nano-line Defects in Photonic Crystal
  9. Tunable High Performance 16-Channel Demultiplexer on 2D Photonic Crystal Ring Resonator Operating at Telecom Wavelengths
  10. Fibers
  11. Experimental Investigation of Intensity Modulator/Direct Detection (IM/DD) Optical OFDM System with Fiber Bragg Grating (FBG)
  12. Integrated Optics
  13. A Novel Proposal for All-Optical OR/AND Gate Using Nonlinear Photonic Crystal Ring Resonators
  14. Design and Implementation of Electro-Optic 2×2 Switch and Optical Gates using MZI
  15. Networks
  16. A Survey of Dynamic Bandwidth Assignment Schemes for TDM-Based Passive Optical Network
  17. Systems
  18. PIIN Cancellation Using a Novel Receiving Architecture for Spectral/Spatial SAC-OCDMA System
  19. Design of Multiservice Code (MS) in Spectral/Temporal/Spatial Domain for OCDMA System
  20. Enhanced Performances of SAC-OCDMA System by Using Polarization Encoding
  21. PAPR Reduction in MIMO-OFDM System Using SLM Without SI
  22. Companding Schemes for Reducing PAPR in OFDM System: A Review
https://doi.org/10.1515/joc-2017-0179
Keywords for this article
multi diagonal code; optical code division multiple access; modified direct detection; phase induced intensity noise

Articles in the same Issue

  1. Frontmatter
  2. Amplifiers
  3. Automatic Gain-Controlled HOA with Residual Pumping
  4. Performance Evaluation of DPSK System with Different Combination of Hybrid Optical Amplifiers by Using Equal and Unequal Channel Spacing
  5. Devices
  6. Investigation of Photonic Integrated Circuits with Low-Loss Bragg Gratings
  7. Design and Performance Analysis of MZI Based 2×2 Reversible XNOR Logic Gate
  8. Design and Numerical Analysis of an All-optical 4-channel Power Splitter in E, S, C, L, and U Bands via Nano-line Defects in Photonic Crystal
  9. Tunable High Performance 16-Channel Demultiplexer on 2D Photonic Crystal Ring Resonator Operating at Telecom Wavelengths
  10. Fibers
  11. Experimental Investigation of Intensity Modulator/Direct Detection (IM/DD) Optical OFDM System with Fiber Bragg Grating (FBG)
  12. Integrated Optics
  13. A Novel Proposal for All-Optical OR/AND Gate Using Nonlinear Photonic Crystal Ring Resonators
  14. Design and Implementation of Electro-Optic 2×2 Switch and Optical Gates using MZI
  15. Networks
  16. A Survey of Dynamic Bandwidth Assignment Schemes for TDM-Based Passive Optical Network
  17. Systems
  18. PIIN Cancellation Using a Novel Receiving Architecture for Spectral/Spatial SAC-OCDMA System
  19. Design of Multiservice Code (MS) in Spectral/Temporal/Spatial Domain for OCDMA System
  20. Enhanced Performances of SAC-OCDMA System by Using Polarization Encoding
  21. PAPR Reduction in MIMO-OFDM System Using SLM Without SI
  22. Companding Schemes for Reducing PAPR in OFDM System: A Review
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 13.9.2025 from https://www.degruyterbrill.com/document/doi/10.1515/joc-2017-0179/html
Scroll to top button