Efficient implementation of optical scanning holography in cancelable biometrics

This paper presents a new trend in biometric security systems, which is cancelable multi-biometrics. In general, traditional biometric systems depend on a single biometric for identification. These traditional systems are subject to different types of attacks. In addition, a biometric signature may...

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Bibliographic Details
Published in:Applied optics (2004) 2021-05, Vol.60 (13), p.3659
Main Authors: Abd El-Samie, Fathi E, Nassar, Rana M, Safan, Mohamed, Abdelhamed, Mohamed A, Khalaf, Ashraf A M, El Banby, Ghada M, Zahran, Osama, El-Rabaie, El-Sayed M, Mohamed, Abdelnaser A, El-Dokany, Ibrahim M, H Ahmed, HossamElDin, El-Khamy, Said, Ramadan, Noha, Soliman, Randa F, El-Shafai, Walid
Format: Article
Language:English
Subjects:
Biometrics
Deformation
Discrete cosine transform
Holography
Scanning
Security systems
Signatures
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Summary:This paper presents a new trend in biometric security systems, which is cancelable multi-biometrics. In general, traditional biometric systems depend on a single biometric for identification. These traditional systems are subject to different types of attacks. In addition, a biometric signature may be lost in hacking scenarios; for example, in the case of intrusion, biometric signatures can be stolen forever. To reduce the risk of losing biometric signatures, the trend of cancelable biometrics has evolved by using either deformed or encrypted versions of biometrics for verification. In this paper, several biometric traits for the same person are treated to obtain a single cancelable template. First, optical scanning holography (OSH) is applied during the acquisition of each biometric. The resulting outputs are then compressed simultaneously to generate a unified template based on the energy compaction property of the discrete cosine transform (DCT). Hence, the OSH is used in the proposed approach as a tool to generate deformed versions of human biometrics in order to get the unified biometric template through DCT compression. With this approach, we guarantee the possibility of using multiple biometrics of the same user to increase security, as well as privacy of the new biometric template through utilization of the OSH. Simulation results prove the robustness of the proposed cancelable multi-biometric approach in noisy environments.
ISSN:1559-128X
2155-3165
DOI:10.1364/AO.415523