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基于离散变换和矩阵旋转的可取消面部与指纹识别用于生物特征安全应用

Discrete Transforms and Matrix Rotation Based Cancelable Face and Fingerprint Recognition for Biometric Security Applications.

作者信息

Algarni Abeer D, El Banby Ghada, Ismail Sahar, El-Shafai Walid, El-Samie Fathi E Abd, Soliman Naglaa F

机构信息

Faculty of Computer and Information Sciences, Princess Nourah Bint Abdulrahman University, Riyadh 84428, Saudi Arabia.

Department of Industrial Electronics and Control Engineering, Faculty of Electronic Engineering, Menoufia University, Menouf 32952, Egypt.

出版信息

Entropy (Basel). 2020 Nov 30;22(12):1361. doi: 10.3390/e22121361.

DOI:10.3390/e22121361
PMID:33266337
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7761353/
Abstract

The security of information is necessary for the success of any system. So, there is a need to have a robust mechanism to ensure the verification of any person before allowing him to access the stored data. So, for purposes of increasing the security level and privacy of users against attacks, cancelable biometrics can be utilized. The principal objective of cancelable biometrics is to generate new distorted biometric templates to be stored in biometric databases instead of the original ones. This paper presents effective methods based on different discrete transforms, such as Discrete Fourier Transform (DFT), Fractional Fourier Transform (FrFT), Discrete Cosine Transform (DCT), and Discrete Wavelet Transform (DWT), in addition to matrix rotation to generate cancelable biometric templates, in order to meet revocability and prevent the restoration of the original templates from the generated cancelable ones. Rotated versions of the images are generated in either spatial or transform domains and added together to eliminate the ability to recover the original biometric templates. The cancelability performance is evaluated and tested through extensive simulation results for all proposed methods on a different face and fingerprint datasets. Low Equal Error Rate (EER) values with high AROC values reflect the efficiency of the proposed methods, especially those dependent on DCT and DFrFT. Moreover, a comparative study is performed to evaluate the proposed method with all transformations to select the best one from the security perspective. Furthermore, a comparative analysis is carried out to test the performance of the proposed schemes with the existing schemes. The obtained outcomes reveal the efficiency of the proposed cancelable biometric schemes by introducing an average AROC of 0.998, EER of 0.0023, FAR of 0.008, and FRR of 0.003.

摘要

信息安全对于任何系统的成功都是必不可少的。因此,需要有一个强大的机制来确保在允许任何人访问存储的数据之前对其进行验证。所以,为了提高用户抵御攻击的安全级别和隐私性,可以采用可撤销生物识别技术。可撤销生物识别技术的主要目标是生成新的失真生物特征模板,以存储在生物识别数据库中,而不是原始模板。本文提出了基于不同离散变换的有效方法,如离散傅里叶变换(DFT)、分数傅里叶变换(FrFT)、离散余弦变换(DCT)和离散小波变换(DWT),此外还通过矩阵旋转来生成可撤销生物特征模板,以满足可撤销性并防止从生成的可撤销模板中恢复原始模板。在空间域或变换域中生成图像的旋转版本,并将它们相加,以消除恢复原始生物特征模板的能力。通过对不同面部和指纹数据集上所有提出的方法进行广泛的仿真结果,评估和测试了可撤销性性能。低等错误率(EER)值和高曲线下面积(AROC)值反映了所提出方法的效率,特别是那些依赖于DCT和DFrFT的方法。此外,进行了一项比较研究,以从安全角度评估所提出的方法与所有变换方法,选择最佳方法。此外,还进行了比较分析,以测试所提出方案与现有方案的性能。获得的结果表明,所提出的可撤销生物识别方案效率高,平均AROC为0.998,EER为0.0023,误识率(FAR)为0.008,拒识率(FRR)为0.003。

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本文引用的文献

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Convolutional neural networks approach for multimodal biometric identification system using the fusion of fingerprint, finger-vein and face images.基于指纹、指静脉和面部图像融合的多模态生物特征识别系统的卷积神经网络方法。
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Double random phase encoding for cancelable face and iris recognition.用于可取消面部和虹膜识别的双随机相位编码
Appl Opt. 2018 Dec 10;57(35):10305-10316. doi: 10.1364/AO.57.010305.
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基于干扰的方法中使用拼图变换去除轮廓的光学图像加密及用单个空间光调制器进行解密
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