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Image transmission over mobile Bluetooth networks with enhanced data rate packets and chaotic interleaving

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Abstract

Bluetooth is a wireless personal area network. This type of networks is widely used for image communication. This paper presents a study for the transmission of images over mobile Bluetooth networks. It presents a novel chaotic interleaving scheme for this purpose. In this scheme, the chaotic Baker map is used for bit interleaving and enhanced data rate packets are used for data transmission. In the proposed scheme, the chaotic interleaver can be applied on the whole bit stream or on a packet-by-packet basis. The proposed scheme is applied with 2DH1, 2DM1, 3DH5, and 3DM5 packets. A comparison study between the proposed scheme and the traditional interleaving schemes for image transmission over correlated and uncorrelated fading channels is presented. The simulation results show the superiority of the proposed scheme over the traditional schemes. The proposed scheme also adds a degree of security to data transmission.

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References

  1. Mohamed, M. A. M., Abou El-Azm, A., El-Fishwy, N., El-Tokhy, M. A. R., & Abd El-Samie, F. E. (2008). Optimization of Bluetooth packet format for efficient performance. Progress in Electromagnetic Research M, 1, 101–110.

    Article  Google Scholar 

  2. Meghanathan, N. (2009). Impact of range of simulation time and network shape on the hop count and stability of routes in mobile ad hoc networks. IENG International Journal of Computer Science, 1, 1–7.

    Google Scholar 

  3. Mohamed, M. A. M., Abou El-Azm, A., El-Fishawy, N. A., El-Tokhy, M. A. R., Shawky, F., & Abd El-Samie, F. E. (2008). Bluetooth performance improvement using convolutional codes. In Proceedings of the 2nd international conference on electrical systems design & technologies, Hammamet Tunisia.

  4. Johansson, P., Kapoor, R., Kazantzidis, M., & Gerla, M. (2001). Bluetooth: An enabler for personal area networking. IEEE Network Magazine, 15(5), 28–37.

    Article  Google Scholar 

  5. Mohamed, M. A. M., Abou El-Azm, A. E., El-Fishawy, N. A., El-Tokhy, M. A. R., Shawky, F., & Abd El-Samie, F. E. (2009). Bluetooth performance improvement using convolutional codes. Journal of Automation & Systems Engineering, 3(1), 1–10.

    Google Scholar 

  6. Mohamed, M. A. M., Abou El-Azm, A., El-Fishawy, N. A., El-Tokhy, M. A. R., Shawky, F., & Abd El-Samie, F. E. (2008). Bluetooth performance improvement over different channels through channel coding. In Proceedings of the 5th international multi-IEEE conference on systems, signals and devices, Jordan.

  7. Galli, S., Famolari, D., & Kodama, T. (2004). Bluetooth: Channel coding considerations. In IEEE vehicular technology conference, Vol. 5, pp. 2605–2609.

  8. Golmie, N., Van Dck, R. E., & Soltanian, A. (2001). Interference of Bluetooth and IEEE 802.11: Simulation modeling and performance evaluation. In Proceedings ACM international workshop on modeling, analysis, and simulation of wireless and mobile systems, Italy.

  9. Chui, T. Y., Thaler, F., & Scanlon, W. G. (2002). A novel channel modeling technique for performance analysis of bluetooth baseband packets. In Proceedings of the IEEE ICC conference, New York.

  10. Haartsen, J. C., & Zürbes, S. (1999) Bluetooth voice and data performance in 802.11 DS WLAN environment. Ericsson Report.

  11. Vafi, S., & Wysocki, T. (2005). Performance of convolutional interleavers with different spacing parameters in turbo codes. In Proceedings of the 6th Australian workshop on communications theory, pp. 8–12.

  12. Nguyen, V. D., & Kuchenbecker, H. (2001). Block interleaving for soft decision viterbi decoding in ofdm systems. IEEE Vehicular Technology Conference, 1, 470–474.

    Google Scholar 

  13. Mohamed El-Bendary, M. A., Abou-El-azm, A. E., El-Fishawy, N. A., Hagagg, A., Shawki, F., & Abd El-Samie, F. E. (2010). Real-time audio signal transmission over the ACL link in Bluetooth systems. In Proceedings of the URSI National Radio Science Conference (NRSC), Cairo, Egypt.

  14. Farag, E. N., & Elmasry, M. I. (1999). Mixed signal VLSI wireless design circuits and system (1st ed.). Dordrecht: Kluwer.

    Google Scholar 

  15. Shi, Y. Q., Zhang, X. M., Ni, Z.-C., & Ansari, N. (2004). Interleaving for combating bursts of errors. IEEE Circuts and Systems Magazine, 4, 29–42 (first quarter).

    Article  Google Scholar 

  16. Vafi, S., & Wysocki, T. A. (2006). Application of convolutional interleavers in turbo codes with unequal error protection. Journal of Telecommunication and Information Technology, 1, 17–23.

    Google Scholar 

  17. Vovatzis, G., & Pitas, I. (1998). Chaotic watermarks for embedding in the spatial digital image domain. Proceeding of IEEE International Conference Image Processing, 2, 432–436.

    Google Scholar 

  18. Lu, W., Tao, H., & Chung, F. (2005). Chaos-based spread spectrum robust watermarking in DWT domain. In Fourth international conference on machine learning and cybernetics, Guangzhou.

  19. Abd El-Samie, F. E., Hassan, E. S., Zhu, X., El-Khamy, S. E., Dessouky, M. I., & El-Dolil, S. A. (2010). A chaotic interleaving scheme for the continuous phase modulation based single-carrier frequency-domain equalization system. Wireless Personal Communications, 11.

  20. Jovic, B., & Unsworth, C. (2007). Chaos-based multi-user time division multiplexing communication system. IET Communications, 1(4), 1751–8628.

    Article  Google Scholar 

  21. Matthews, R. (1998). On the derivation of a chaotic encryption algorithm. Cryptologia, XIII(1), 29–41.

    MathSciNet  Google Scholar 

  22. Deffeyes, K. S. (1991). Encryption system and method. US Patent, no. 5001754, March 1991.

  23. Fridrich, J. (1998). Symmetric ciphers based on two-dimensional chaotic maps. International Journal of Bifurcation and Chaos, 8, 1259–1284.

    Article  MathSciNet  MATH  Google Scholar 

  24. Fridrich, J. (1997). Image encryption based on chaotic maps. In Proceedings of the IEEE international conference on systems, man, and cybernetics, pp. 1105–1110.

  25. Qian, Q., Chen, Z., & Yuan, Z. (2008). Video compression and encryption based-on multiple chaotic system. In Proceedings of the 3rd intetnational conference on innovative computing information and control (ICICIC’08).

  26. Chockalingam, A., & Zorzi M. (1998). Energy efficiency of media access protocols for mobile data networks. IEEE Transactions on Communications, 46(11), 1418–1421.

    Article  Google Scholar 

  27. Jakes, W. C. (1975). Microwave mobile communications. New York: Wiley. ISBN 0-471-43720-4.

    Google Scholar 

  28. Ozarow, L., Shamai, S., & Wyner, A. D. (1994). Information theoretic considerations for cellar mobile radio. IEEE Vehicular Technology Conference, 43, 359–378.

    Article  Google Scholar 

  29. Aldrich. Correlations genuine and spurious in Pearson and Yule. Statistical Science, 10, 364–376. http://www.jstor.org/stable/2246135.

  30. Zanella, A., & Zorzi, M. (2008). Throughput and energy efficiency of Bluetooth v2 + EDR in fading channels. In IEEE Communications Society Subject Matter Experts for Publication in the WCNC 2008 Proceedings.

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Authors and Affiliations

  1. Department of Communication Technology, Faculty of Industrial Education, Helwan University, Helwan, Egypt

    M. A. M. El-Bendary & M. El-Tokhy

  2. Department of Electronics and Electrical Communications, Faculty of Electronic Engineering, Menoufia University, Menouf, 32952, Egypt

    A. E. Abou-El-Azm, F. Shawki & F. E. Abd El-Samie

  3. Department of Computer Engineering and Sciences, Faculty of Electronic Engineering, Menoufia University, Menouf, 32952, Egypt

    N. A. El-Fishawy

  4. Intelligent Systems Research Centre, Faculty of Computing, London Metropolitan University, London, UK

    H. B. Kazemian

Authors
  1. M. A. M. El-Bendary
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  2. A. E. Abou-El-Azm
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  3. N. A. El-Fishawy
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  4. F. Shawki
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  5. M. El-Tokhy
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  6. F. E. Abd El-Samie
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  7. H. B. Kazemian
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Corresponding author

Correspondence to F. E. Abd El-Samie.

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El-Bendary, M.A.M., Abou-El-Azm, A.E., El-Fishawy, N.A. et al. Image transmission over mobile Bluetooth networks with enhanced data rate packets and chaotic interleaving. Wireless Netw 19, 517–532 (2013). https://doi.org/10.1007/s11276-012-0482-8

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  • DOI: https://doi.org/10.1007/s11276-012-0482-8

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