Fast physical random bit generation with chaotic semiconductor lasers (original) (raw)

References

  1. Eastlake, D., Schiller, J., & Crocker, S. Randomness requirements for security. Available at http://tools.ietf.org/html/rfc4086 RFC4086 2005.
  2. Security requirements for cryptographic modules. Available at http://csrc.nist.gov/publications/fips/fips140-2/fips1402.pdf FIPS 140-2 (2001).
  3. Metropolis, N., & Ulam, S. The Monte Carlo method. J. Am. Statist. Assoc. 44, 335–341 (1949).
    Article Google Scholar
  4. Gisin, N., Robordy, G., Tittel, W., & Zbinden, H. Quantum cryptography. Rev. Modern Phys. 74, 145–195 (2002).
    Article ADS Google Scholar
  5. Marsaglia, G. DIEHARD: A battery of tests of randomness. Available at http://stat.fsu.edu/∼geo (1996).
  6. Rukhin, A. et al. A statistical test suite for random and pseudorandom number generators for cryptographic applications. National Institute of Standards and Technology, Special Publication 800-22 (2001).
  7. Kim, S. J., Umeno, K. & Hasegawa, A. Corrections of the NIST statistical test suite for randomness. arXiv:nlin.CD/0401040v1 (2004).
  8. Galton, F. Dice for statistical experiments. Nature 42, 13–14 (1890).
    Article ADS Google Scholar
  9. Knuth, D. The Art of Computer Programming: Volume 2: Seminumerical Algorithms 3rd edn (Addison-Wesley Professional, 1996).
  10. Kelsey, J. Entropy and Entropy Sources in X9.82 (NIST, 2004).
  11. Schindler, W. & Killmann, W. Evaluation criteria for true (physical) random number generators used in cryptographic applications. CHES 2002, Lecture Notes in Computer Science 2523, 431–449 (2002).
    MATH Google Scholar
  12. Jun, B. & Kocher, P. The Intel random number generator. White paper prepared for Intel Corporation, Cryptography Research Inc. Available at http://www.cryptography.com/resources/whitepapers/IntelRNG.pdf. (1999).
  13. Holman, W. T., Connelly, J. A. & Dowlatabadi, A. B. An integrated analog/digital random noise source. IEEE Trans. Circuits and Systems I 44, 521–528 (1997).
    Article Google Scholar
  14. Dynes, J. F., Yuan, Z. L., Sharpe, A. W. & Shields, A. J. A high speed, post-processing free, quantum random number generator, arxiv/0807.4111v1 (July 2008).
  15. Cortigiani, F., Petri, C., Rocchi, S. & Vignoli, V. Very high-speed true random noise generator. The 7th IEEE International Conference on Electronics, Circuits and Systems, 2000 (ICECS 2000) 1, 120–123 (2000).
  16. Bucci, M., Germani, L., Luzzi, R., Trifiletti, A. & Varanouvo, M. A high-speed oscillator-based truly random number source for cryptographic applications on a Smart Card IC. IEEE Trans. Comput. 52, 403–409 (2003).
    Article Google Scholar
  17. Tokunaga, C., Blaauw, D. & Mudge, T. True random number generator with a metastability-based quality control. IEEE J. Solid-State Circuits 43, 78–85 (2008).
    Article ADS Google Scholar
  18. Ornstein, D. S. Ergodic theory, randomness and ‘chaos’. Science 243, 182–187 (1989).
    Article ADS MathSciNet Google Scholar
  19. Wolfram, S. Random sequence generation by cellular automaton. Adv. Appl. Math. 7, 123–169 (1986).
    Article MathSciNet Google Scholar
  20. Stojanovski, T. & Kocarev, L. Chaos-based random number generators-part I: analysis [cryptography]. IEEE Trans. Circ. Syst. I: Fund. Theory Appl. 48, 281–288 (2001).
    Article Google Scholar
  21. Pappu, R., Recht, B., Taylor, J. & Gershenfeld, N. Physical one-way functions. Science 297, 2026–2030 (2002).
    Article ADS Google Scholar
  22. Gleeson, J. T. Truly random number generator based on turbulent electroconvection. Appl. Phys. Lett. 81, 1949–1951 (2002).
    Article ADS Google Scholar
  23. Callegari, S., Rovatti, R. & Setti, G. Embeddable ADC-based true random number generator for cryptographic applications using nonlinear signal processing and chaos. IEEE Trans. Signal Process. 53, 793–805 (2005).
    Article ADS MathSciNet Google Scholar
  24. VanWiggeren, G. D. & Roy, R. Communication with chaotic lasers. Science 279, 1198–1200 (1998).
    Article ADS Google Scholar
  25. Argyris, A. et al. Chaos-based communications at high bit rates using commercial fibre-optic links. Nature 438, 343–346 (2005).
    Article ADS Google Scholar
  26. Liu, J. M., Chen, H. F. & Tang, S. Synchronized chaotic optical communications at high bit rates. IEEE J. Quant. Electron. 38, 1184–1196 (2002).
    Article ADS Google Scholar
  27. Lang, R. & Kobayashi, K. External optical feedback effects on semiconductor injection laser properties. IEEE J. Quant. Electron. 16, 347–355 (1980).
    Article ADS Google Scholar
  28. Uchida, A., Liu, Y. & Davis, P. Characteristics of chaotic masking in synchronized semiconductor lasers. IEEE J. Quant. Electron. 39, 963–970 (2003).
    Article ADS Google Scholar
  29. Bracikowski, C., Fox, R. F. & Roy, R. Amplification of intrinsic noise in a chaotic multimode laser system. Phys. Rev. A 45, 403–408 (1992).
    Article ADS Google Scholar
  30. Uchida, A., Heil, T., Liu, Y., Davis, P. & Aida, T. High-frequency broad-band signal generation using a semiconductor laser with a chaotic optical injection. IEEE J. Quant. Electron. 39, 1462–1467 (2003).
    Article ADS Google Scholar

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