Multi-Level of DNA Encryption Technique Based on DNA Arithmetic and Biological Operations

D. A. Zebari, H. Haron, Subhi R. M. Zeebaree, Diyar Qader Zeebaree
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引用次数: 27

Abstract

Networks have evolved very rapidly, which allow secret data transformation speedily through the Internet. However, the security of secret data has posed a serious threat due to openness of these networks. Thus, researchers draw their attention on cryptography field for this reason. Due to the traditional cryptographic techniques which are vulnerable to intruders nowadays. Deoxyribonucleic Acid (DNA) considered as a promising technology for cryptography field due to extraordinary data density and vast parallelism. With the help of the various DNA arithmetic and biological operations are also Blum Blum Shub (BBS) generator, a multi-level of DNA encryption algorithm is proposed here. The algorithm first uses the dynamic key generation to encrypt sensitive information as a first level; second, it uses BBS generator to generate a random DNA sequence; third, the BBS-DNA sequence spliced with a DNA Gen Bank reference to produce a new DNA reference. Then, substitution, permutation, and dynamic key are used to scramble the new DNA reference nucleotides locations. Finally, for further enhanced security, an injective mapping is established to combine encrypted information with encrypted DNA reference using Knight tour movement in Hadamard matrix. The National Institute of Standard and Technology (NIST) tests have been used to test the proposed algorithm. The results of the tests demonstrate that they effectively passed all the randomness tests of NIST which means they can effectively resist attack operations.
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基于DNA算术和生物运算的DNA多级加密技术
网络的发展非常迅速,这使得秘密数据可以通过Internet快速转换。然而,由于这些网络的开放性,机密数据的安全受到了严重的威胁。因此,研究人员开始关注密码学领域。由于传统的加密技术容易受到入侵者的攻击。脱氧核糖核酸(DNA)由于其惊人的数据密度和巨大的并行性而被认为是一种很有前途的密码技术。借助各种DNA算法和生物运算以及Blum Blum Shub (BBS)生成器,提出了一种多层次的DNA加密算法。该算法首先采用动态密钥生成作为一级加密敏感信息;其次,利用BBS生成器生成随机DNA序列;第三,将BBS-DNA序列与DNA genbank参考物拼接,生成新的DNA参考物。然后,采用置换、置换和动态密钥等方法来打乱新的DNA参考核苷酸的位置。最后,为了进一步提高安全性,利用Hadamard矩阵中的Knight tour运动,建立了一种将加密信息与加密DNA参考相结合的注入映射。美国国家标准与技术研究所(NIST)的测试已用于测试所提出的算法。测试结果表明,它们有效地通过了NIST的所有随机性测试,这意味着它们可以有效地抵御攻击操作。
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