Cryptographic Key Generation Using Biometrics

Cryptographic Key Generation Using Biometrics 6,7/10 3378 reviews

The contribution of this research is a cryptographic key (re)generation scheme based on biometrics. /boson-exam-experiment-activation-key-generator.html. The scheme is comprised of the following components: A client/server model is developed for privacy preserving cryptographic key regeneration; where the decryption key - no (encrypted) personal data - is stored in the server. Aug 24, 2006 Cryptographic Key Generation from Biometric Data Using Lattice Mapping Abstract: Crypto-biometric systems are recently emerging as an effective process of key management to address the security weakness of conventional key release systems using pass-codes, tokens or pattern recognition based biometrics. The beauty of using biometrics to lock your secret key is that, like all other cryptographic solutions on Android, all sensitive operations between the biometrics system and the Android Keystore. The construction of cryptographic key from biometrics is used to make safe our system. To implement this concept, sender’s recent fingerprint would be used to construct key by combining it. And biometric-based cryptographic key generation targeted in this work. The former relies on good classifiers or user-specific templates to distinguish authentic user to potential imposters, while the latter transforms biometric features to a unique key that cannot be regenerated from biometric features of potential imposters. The goal of biometric. The generation of cryptographic key from individual user’s biometric feature is a solution to this problem. Poweriso 5.9 key generator. In this approach, it is too hard for the attacker to guess the cryptographic key without the prior knowledge of the user’s biometrics. But the problem with biometrics is that compromise makes it unusable.

Cryptographic Key Generation Using Biometrics Key

Using

Free Key Generation Software

  1. W. Stallings, Cryptography and Network Security: Principles and Practice, 5th edition, Prentice Hall, 2010.Google Scholar
  2. Soutar, C.; Roberge, A. and Vijaya Kumar, B.V.K., “Biometric Encryption using Image Processing”, SPIE, pp. 178–188, 1998.Google Scholar
  3. Bolle, R.M.; Connel, J.H. and Ratha, N.K., “Biometrics Perils and Patches”, Elsevier - Pattern Recognition 35, pp. 2727–2738, 2002.Google Scholar
  4. Teoh, Andrew B.J.; Goh, A. and Ngo, D.C.L., “Random MultispaceQuantisation as an Analytic Mechanism for BioHashing of Biometric and Random Identity Inputs”, IEEE Transactions on Pattern Analysis and Machine Intelligence 28(12), pp. 1892–1901, 2006.Google Scholar
  5. Ratha, N.K.; Chikkerur, S.; Connell, J.H. and Bolle, R.M., “Generating Cancelable Fingerprint Templates”, IEEE Transactions on Pattern Analysis and Machine Intelligence, 29(4), pp. 561–572, 2007.Google Scholar
  6. Tulyakov, S.; Farooq, F. and Govindaraju, V., “Symmetric Hash Functions for Fingerprint Minutiae”, International Workshop on Pattern Recognition for Crime Prevention, Security and Surveillance (ICAPR 2005), 3687, pp. 30–38, 2005.Google Scholar
  7. Ang, R.; Rei, S.N. and McAven, L., “Cancelable Key-Based Fingerprint Templates”, Information Security and Privacy: 10th Australasian Conference (ACISP 2005), pp. 242–252, 2005.Google Scholar
  8. Maiorana, E.; Campisi, P.; Fierrez, J. and Ortega-Garcia, J., “Cancelable Templates for Sequence Based Biometrics with Application to On-line Signature Recognition”, IEEE Transactions on Systems, 40(3), pp. 525–538, 2010.Google Scholar
  9. Nanni, L. and Lumini, A., “Cancelable Biometrics: Problems and Solutions for Improving Accuracy”, NovaPublisher - Biometrics: Methods, Applications and Analysis, chap-7, pp. 153–166, 2010.Google Scholar
  10. F Monrose, MK Reiter, Q Li, S Wetzel, “Cryptographic key generation from voice”, Proceedings of IEEE Symposium on Security and Privacy, pp. 202–213, 2011.Google Scholar
  11. H Feng, CC Wah, “Private Key generation from on-line hand written signatures”, Information Management & Computer Security, 10(4), pp. 159–164, 2002.Google Scholar
  12. B Chen, V Chandran, “Biometric Based Cryptographic Key Generation from Faces”, Proceedings of 9th Biennial Conference of the Australian Pattern Recognition Society on Digital Image Computing Techniques and Applications, pp. 394–401, 2007.Google Scholar
  13. A Jagadeesan, K Duraiswamy, “Secured Cryptographic Key Generationfrom Multimodal Biometrics: Feature Level Fusion of Fingerprint and Iris”, Int. Journalon Computer Sc. & Information Security, 7(2), pp. 28–37, 2010.Google Scholar
  14. A Jagadeesan, T Thillaikkarasi, K Duraiswamy, “Cryptographic KeyGeneration from Multiple Biometrics Modalities: Fusing Minutiae with Iris Feature”, Int. J. Comput. Appl. 2(6), pp. 16–26, 2010.Google Scholar
  15. C Rathgeb, A Uhl., “Context-based biometric key generation for Iris”, IET Computer Vision, 5(6), pp. 389–397, 2011.Google Scholar
  16. D. Milao Q. Tang, and W. Fu, “Fingerprint minutia extraction based on principal curves,” Pattern Recognition Letters, Vol. 28, Issue 16, pp. 2184–2189, 2009.Google Scholar