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Distributed Restoration in Optical Networks using Feed-forward Neural Networks

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Abstract.

A new method is proposed for determining protection paths in an optical network where users have different characteristics in terms of reliability needs and security restrictions. Survivability is achieved by distributed mesh protection. Over the preplanned primary and backup capacity, optimal routing and wavelength assignment is carried out. In case of a network failure, protection routes and optimum flow values on these protection routes are extracted from a previously trained feed-forward neural network which is distributed over the optical data communications network.

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References

  1. N. Ghani S. Dixit T.S. Wang (2000) ArticleTitleOn IP over WDM Integration IEEE Commun. Magaz. 38 IssueID3 72–84 Occurrence Handle10.1109/35.825644

    Article  Google Scholar 

  2. R. Iraschko W.D. Grover (2000) ArticleTitleA highly efficient path-restoration protocol for management of optical network transport integrity IEEE J. Selected Areas Commun. 18 IssueID5 779–794 Occurrence Handle10.1109/49.842993

    Article  Google Scholar 

  3. Chujo T. et al.: The design and simulation of an intelligent transport network with distributed control. Proceedings of Network Operations Management Symposium’90 vol. 11(4). San Diego, CA, USA (1990)

  4. Iraschko, R., MacGregor, M.H., Grover, W.D.: Optimal capacity placement for path restoration in mesh survivable networks. Proceedings of IEEE International Conference on Communication’96, vol. 1, pp. 1568–1574. Dallas, TX, USA (1996)

  5. K. Murakami H.S. Kim (1998) ArticleTitleOptimal capacity and flow assignment for self-healing ATM networks based on line and end-to-end restoration IEEE/ACM Transac. Netw. 6 IssueID2 207–221 Occurrence Handle10.1109/90.664269

    Article  Google Scholar 

  6. Sakauchi, H., Nishimura, Y., Hasegawa S.: A self-healing network with an economical spare channel assignment. Proceeding of IEEE Globecom’90, (San Diego, CA, USA (1990) pp. 438–443

  7. B.T. Doshi S. Dravida P. Harshavardana O. Hauser Y. Wang (1999) ArticleTitleOptical network design and restoration Bell Labs Tech. J. 4 IssueID1 58–84 Occurrence Handle10.1002/bltj.2147

    Article  Google Scholar 

  8. Liu, Y., Tipper, D.: Multilayer network survivability models and application. http://citeseer.nj.nec.com/540678.html.

  9. Basbugoglu, O., Bilgen, S.: Distributed routing and wavelength assignment in WDM Networks. Ph.D. thesis, Graduate School of Natural Applied Sciences of Middle East Technical University, Ankara, Turkey (2000).

  10. R. Irachko M.H. McGregor (1998) ArticleTitleOptimal capacity placement for path restoration in STN or ATM mesh survivable networks IEE/ACM Transact. Netw. 6 IssueID3 325–336 Occurrence Handle10.1109/90.700896

    Article  Google Scholar 

  11. G.P. Austin B.T. Doshi C.J. Hunt R. Nagarajan M.A. Qureshi (2001) ArticleTitleFast, scalable and distributed restoration in general mesh optical networks Bell Labs Tech. J. 6 IssueID1 67–81 Occurrence Handle10.1002/bltj.2264

    Article  Google Scholar 

  12. R. Battiti G. Tecchiolli (1995) ArticleTitleTraining neural nets with the reactive tabu search IEEE Transact. Neural Netw. 6 IssueID5 1185–1200 Occurrence Handle10.1109/72.410361

    Article  Google Scholar 

  13. W. Schiffmann M. Joost (1998) ArticleTitleSpeeding up backpropagation algorithms by using cross-entropy combined with pattern normalization Int. J. Uncertain. Fuzziness Knowledge Based Syst. 6 IssueID2 117–126 Occurrence Handle10.1142/S0218488598000100 Occurrence Handle1087.68617

    Article  MATH  Google Scholar 

  14. Berthold, M.R., Sudweeks, F., Newton, S., Coyne, R.: Clustering on the net: applying an autoassociative neural network to computer-mediated discussions. http://jcmc.huji.ac.il/vol2/issue4/berthold.html#Berthold97

  15. Russel, S.J., Norvig, P.: Artificial Intelligence A Modern Approach. Prentice Hall, NJ, (1995)

  16. Peterson, C.: Combinatorial optimization with feedback artificial neural networks. Proceedings of ICANN 1995 International Conference on Artificial Neural Networks. pp. 260–270. (Paris, France (1995)

  17. X. Yao (1992) ArticleTitleFinding approximate solutions to NP-Hard problems by neural networks is hard, Inf Process. Lett. 41 IssueID2 93–98 Occurrence Handle0743.68082 Occurrence Handle1156832 Occurrence Handle10.1016/0020-0190(92)90261-S

    Article  MATH  MathSciNet  Google Scholar 

  18. Chen, M.S.: Analysis and design of multi layer perceptron using polynomial basisfunctions. Ph.D. thesis, University of Texas, Arlington (1996)

  19. Basbugoglu, O., Bilgen, S.: A distributed minimal congestion routing algorithm for WDM networks. Proceedings of the International Symposium on Computer and Information Sciences XIV (ISCIS XIV), pp. 18–25. Izmir, Turkeys (1999)

  20. MATLAB 6.0.0.88 Release 12 Help File (2000)

  21. Bilgen, S., Koçyigit, A.: Statistically predictive optimal wavelength routing in all-optical networks. Proceedings of the International Symposium on Computer and Information Sciences XV (ISCIS XV), pp. 358–365. Istanbul, Turkey (2000)

  22. Berthold M.R., Sudweeks F., Newton S., Coyne R. It makes sense:using an autoassociative neural network to explore typicality in computer-mediated discussions. Network and Netplay: Virtual Groups on the Internet pp. 191–219. (1998)

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Authors and Affiliations

  1. NATO Consultation, Command and Control Agency, Oude Waalsdorperweg 61, 2597, AK, The Hague, The Netherlands

    Demeter Gokisik Karpat

  2. Department of Electrical and Electronics Engineering, Middle East Technical University, Ankara, 06531, Turkey

    Semih Bilgen

Authors
  1. Demeter Gokisik Karpat
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  2. Semih Bilgen
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Correspondence to Demeter Gokisik Karpat.

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Karpat, D.G., Bilgen, S. Distributed Restoration in Optical Networks using Feed-forward Neural Networks. Photon Netw Commun 12, 53–64 (2006). https://doi.org/10.1007/s11107-006-0014-5

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  • DOI: https://doi.org/10.1007/s11107-006-0014-5

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