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New Generation of Optical NoC System with Wireless CDMA Architecture

  • Hichem Mrabet EMAIL logo und Rabah Attia
Veröffentlicht/Copyright: 4. März 2015
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Journal of Optical Communications
Aus der Zeitschrift Journal of Optical Communications Band 36 Heft 3

Abstract

In this paper, a new generation of Network-on-chip (NoC) system with CDMA code is proposed. A Bipolar CDMA code is used to provide a good system performance and to reduce MAI. Two structures of a detector are employed, which are the PIN and the APD detectors, while putting into consideration thermal noise. On one hand, we are proving, in this work, that system performance can achieve a good BER value in optical context with an acceptable node number. On the other hand, system bandwidth can reach 16 Gbit/s with an acceptable SNR compared to wired architecture.

Keywords: Network-on-Chip(NoC); wireless CDMA; BER; SNR
PACS.: Detectors; Networks; Systems

References

1. ZhangL, YangM, JiangY, RegentovaE, LuE. Generalized wavelength routed optical micronetwork in network-on-chip. In: Proceedings of the 18th IASTED International Conference on Parallel and Distributed Computing and Systems, Special Session on High Performance Interconnection Networks, 698–703, Dallas, TX, Nov. 2006.Suche in Google Scholar

2. DielissenJ, RadulescuA, GoossensK, RijpkemaE. Concepts and implementation of the Philips network-on-chip. In: IP-Based SOC Design, Grenoble, 2003.Suche in Google Scholar

3. GirodiasB, BouchebabaY, NicolescuG, MieyevilleF, GaffiotF, O’ConnorI. System level assessment of an optical NoC in an MPSoC platform. In: Design, Automation &Test in Europe Conference & Exhibition, DATE’07, 2007.Suche in Google Scholar

4. O’ConnorI, Tissafi-DrissiF, NavarroD, MieyevilleF, GaffiotF, DambreJ, et al. Integrated optical interconnect for on-chip data transport. In: The 4th International IEEE-NEWCAS Conference, Canada, 2006.10.1109/NEWCAS.2006.250937Suche in Google Scholar

5. AgrawalG. Fiber-optic communications systems. 3rd ed. New York: Wiley-Interscience Publication, 2002.Suche in Google Scholar

6. PrucnalR. Optical code division multiple access: fundamentals and applications. Boca Raton: CRC Press, 2006.Suche in Google Scholar

7. O’ConnorI, BriereM, DrouardE, KazmierczakA, Tissafi-DrissiF, NavarroD, et al. Towards reconfigurable optical networks on chip. ReCoSoC’05.2005.Suche in Google Scholar

8. GuH, XuJ, ZhangW, Low-Power FatA Tree-based Optical Network-on-Chip for Multiprocessor System-on-Chip, EDAA, 2009.10.1109/ISVLSI.2009.19Suche in Google Scholar

9. ZhangL, YangM, JiangY, RegentovaE. Architectures and routing schemes for optical network-on-chips. Comput Electr Eng J2009;35:85677.10.1016/j.compeleceng.2008.09.010Suche in Google Scholar

10. MrabetH, DayoubI, AttiaR, HaxhaS. Performance improving of OCDMA system using 2-d optical codes with optical SIC receiver. J Lightwave Technol2009;27:474453.10.1109/JLT.2009.2026293Suche in Google Scholar

11. YeY, XuJ, WuX, ZhangW, LiuN, NikdastM. A torus-based hierarchical optical-electronic network-on-chip for multiprocessor system-on-chip. ACM J Emerg Technol Comput Syst2012;8:Article 5.10.1145/2093145.2093150Suche in Google Scholar

12. YeY, XuJ, WuX, ZhangW, NikdastM, WangZ, et al. System-level modeling and analysis of thermal effects in optical networks-on-chip. Trans Very Large Scale Integr (VLSI) Syst2013;21:292305.10.1109/TVLSI.2012.2185524Suche in Google Scholar

13. JiR, XuJ, YangL. Five-port optical router based on microring switches for photonic networks-on-chip. IEEE Photonics Technol Lett2013;25:4925.10.1109/LPT.2013.2243427Suche in Google Scholar

14. MichalzikR, EbelingKJ. Operating principles of VCSELs, Optoelectron. Dept., Univ. Ulm, Ulm, Germany, 2003.Suche in Google Scholar

15. JazayerifarM, SalehiJ. Atmospheric optical CDMA Communication systems via optical orthogonal codes. Trans Commun2006;54:161423.10.1109/TCOMM.2006.881245Suche in Google Scholar

Received: 2014-9-15
Accepted: 2015-2-11
Published Online: 2015-3-4
Published in Print: 2015-9-1

©2015 by De Gruyter

Artikel in diesem Heft

  1. Frontmatter
  3. Effect of Raman Amplifier and Cyclic Prefix on O-OFDM System Using Phase Modulation
  4. All-Optical Switching in Ultrashort Photonic Crystal Couplers Modified Y-branch Structure
  5. Nonlinear Phase Shift due to Stimulated Brillouin Scattering in Strong Saturation Regime for Different Types of Fibers
  6. A Novel Weighted Energy Efficient Routing and Spectrum Assignment Algorithm in Flexible Optical Networks
  7. Reception of Polarization-Multiplexed QPSK Using Different Receivers with and without Differential Decoding
  8. RSOA-Based Full-Duplex WDM-PON for 20 Gbps Transmission in Two Channels Over a Long-Haul SMF Using External Modulation Scheme
  9. Physical Layer Impairment Model for CO-OFDM System Considering Amplified Spontaneous Emission and Four-wave Mixing
  10. Suppress the FWM by Increasing Channel Spacing and Chromatic Dispersion of Fiber in WDM System
  11. Performance Analysis of Advanced Modulation Formats at 40 Gbit/s for Single Channel and Multichannel
  12. Effect of Gain and Noise Figure on DPSK Modulated Long-haul Optical Communication System
  13. Effect of Optical Amplifiers on the Performance of SCM Radio over Fiber Systems
  14. New Generation of Optical NoC System with Wireless CDMA Architecture
  15. Intra-channel Cross-Phase Modulation Effect in Dispersion Compensated Single Channel Lightwave System with Negative Residual Dispersion
  16. Effect of Different Scattaring Technique on Higher Order Soliton
https://doi.org/10.1515/joc-2014-0079
Schlagwörter für diesen Artikel
Network-on-Chip(NoC); wireless CDMA; BER; SNR

Artikel in diesem Heft

  1. Frontmatter
  3. Effect of Raman Amplifier and Cyclic Prefix on O-OFDM System Using Phase Modulation
  4. All-Optical Switching in Ultrashort Photonic Crystal Couplers Modified Y-branch Structure
  5. Nonlinear Phase Shift due to Stimulated Brillouin Scattering in Strong Saturation Regime for Different Types of Fibers
  6. A Novel Weighted Energy Efficient Routing and Spectrum Assignment Algorithm in Flexible Optical Networks
  7. Reception of Polarization-Multiplexed QPSK Using Different Receivers with and without Differential Decoding
  8. RSOA-Based Full-Duplex WDM-PON for 20 Gbps Transmission in Two Channels Over a Long-Haul SMF Using External Modulation Scheme
  9. Physical Layer Impairment Model for CO-OFDM System Considering Amplified Spontaneous Emission and Four-wave Mixing
  10. Suppress the FWM by Increasing Channel Spacing and Chromatic Dispersion of Fiber in WDM System
  11. Performance Analysis of Advanced Modulation Formats at 40 Gbit/s for Single Channel and Multichannel
  12. Effect of Gain and Noise Figure on DPSK Modulated Long-haul Optical Communication System
  13. Effect of Optical Amplifiers on the Performance of SCM Radio over Fiber Systems
  14. New Generation of Optical NoC System with Wireless CDMA Architecture
  15. Intra-channel Cross-Phase Modulation Effect in Dispersion Compensated Single Channel Lightwave System with Negative Residual Dispersion
  16. Effect of Different Scattaring Technique on Higher Order Soliton
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