Wavelength-Routed Networks With Lightpath Data Interchanges

We observe that tunable wavelength converters (TWCs) that are traditionally installed in wavelength-routed (WR) networks for wavelength contention resolution can be further utilized to provide fast data switching between lightpaths. This allows us to route a data unit through a sequence of lightpaths from source to destination if a direct single lightpath connection is not available or if we want to minimize the overhead of setting up new lightpaths. Since TWCs have a tuning time of picoseconds, it may be possible to use the installed TWCs as lightpath data interchanges (LPIs) to improve the performance of WR networks without significant optical hardware upgrade. Compared with the multihop electronic grooming approach of lightpath networks, the LPI approach has a simpler WR node architecture, does not need expensive high-speed electrical multiplexers/routers, and does not sacrifice the bit-rate/format transparency of data between the source and destination. Our simulation results show that WR networks with LPIs can have much lower blocking probability than WR networks without LPIs if the traffic duration is short. We show that LPIs can also be used to provide new data transportation services such as optical time division multiplexing access (OTDMA) time-slotted service in WR networks.

[1]  Murali S. Kodialam,et al.  Oblivious routing of highly variable traffic in service overlays and IP backbones , 2009, IEEE/ACM Trans. Netw..

[2]  Chunming Qiao,et al.  Traffic grooming in mesh WDM optical networks - performance analysis , 2004, IEEE Journal on Selected Areas in Communications.

[3]  Joseph E. Ford,et al.  1092 Channel 2-D Array Demultiplexer for Ultralarge Data Bandwidth , 2007, Journal of Lightwave Technology.

[4]  Imrich Chlamtac,et al.  Lightpath communications: an approach to high bandwidth optical WAN's , 1992, IEEE Trans. Commun..

[5]  M. Duser,et al.  Analysis of a dynamically wavelength-routed optical burst switched network architecture , 2002 .

[6]  Dirk Breuer,et al.  Evolution of Terrestrial Optical System and Core Network Architecture , 2006, Proceedings of the IEEE.

[7]  S. Sankaranarayanan,et al.  Comprehensive performance modeling and analysis of multicasting in optical networks , 2003, IEEE J. Sel. Areas Commun..

[8]  P.K.A. Wai,et al.  External wavelength contention resolution for optical crossconnects , 2009, 2009 14th OptoElectronics and Communications Conference.

[9]  Nasir Ghani,et al.  On IP-over-WDM integration , 2000, IEEE Commun. Mag..

[10]  S. Chandrasekhar,et al.  Monolithically integrated 40-gb/s switchable wavelength converter , 2006, Journal of Lightwave Technology.

[11]  V. Li,et al.  A Wavelength-Convertible Optical Network , 1993 .

[12]  Piet Demeester,et al.  Optical networking: past, present and future , 2000 .

[13]  John E. Bowers,et al.  Optical signal processing for optical packet switching networks , 2003, IEEE Commun. Mag..

[14]  Michalis Faloutsos,et al.  Long-range dependence ten years of Internet traffic modeling , 2004, IEEE Internet Computing.

[15]  Bijan Jabbari,et al.  DRAGON: a framework for service provisioning in heterogeneous grid networks , 2006, IEEE Communications Magazine.

[16]  Rouzbeh Razavi,et al.  Multiconstraints fuzzy-logic-based scheduling algorithm for passive optical networks , 2009 .

[17]  Chunming Qiao,et al.  Optical burst switching (OBS) - a new paradigm for an Optical Internet^{1} , 1999, J. High Speed Networks.

[18]  Sandro M. Rossi,et al.  Amplifier placement in metro-scaled wavelength-routed network , 2003 .

[19]  Y. Koike,et al.  Field trial of full-mesh WDM network (AWG-STAR) in metropolitan/local area , 2004, Journal of Lightwave Technology.

[20]  Nicholas F. Maxemchuk,et al.  Routing in the Manhattan Street Network , 1987, IEEE Trans. Commun..

[21]  Jonathan S. Turner,et al.  Terabit burst switching , 1999, J. High Speed Networks.

[22]  Y. Jaouen,et al.  Eight-wavelength Er-Yb doped amplifier: combiner/splitter planar integrated module , 1999, IEEE Photonics Technology Letters.

[23]  S.J.B. Yoo,et al.  Optical Packet and Burst Switching Technologies for the Future Photonic Internet , 2006, Journal of Lightwave Technology.

[24]  I. Bennion,et al.  Error-Free 320-Gb/s All-Optical Wavelength Conversion Using a Single Semiconductor Optical Amplifier , 2007, Journal of Lightwave Technology.

[25]  Yinlei Hao,et al.  A Proposal of Zero Leakage-Loss Passive Optical Combiner Based on Nonreciprocal Waveguide , 2009, IEEE Photonics Technology Letters.

[26]  C. Nuzman,et al.  1100 x 1100 port MEMS-based optical crossconnect with 4-dB maximum loss , 2003, IEEE Photonics Technology Letters.

[27]  Ioannis Tomkos,et al.  Photonics in switching: enabling technologies and subsystem design , 2009 .

[28]  Walter Willinger,et al.  On the self-similar nature of Ethernet traffic , 1993, SIGCOMM '93.

[29]  J.Y. Wei,et al.  Just-in-time signaling for WDM optical burst switching networks , 2000, Journal of Lightwave Technology.

[30]  A. Tajima,et al.  10-Gb/s/port gated divider passive combiner optical switch with single-mode-to-multimode combiner , 1998, IEEE Photonics Technology Letters.

[31]  George N. Rouskas,et al.  Traffic grooming in path, star, and tree networks: complexity, bounds, and algorithms , 2003, IEEE Journal on Selected Areas in Communications.

[32]  Tarek S. El-Bawab,et al.  Optical packet switching in core networks: between vision and reality , 2002, IEEE Commun. Mag..

[33]  Ioannis Tomkos,et al.  Technological challenges on the road toward transparent networking , 2008 .

[34]  Minho Kang,et al.  Traffic Share-Based Multicast Scheduling for Broadcast Video Delivery in Shared-WDM-PONs , 2007, Journal of Lightwave Technology.