A new color image encryption scheme based on DNA encoding and spatiotemporal chaotic system

• Published in: Signal processing. Image communication Vol. 80; p. 115670
• Main Authors: Xuejing, Kang, Zihui, Guo
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier B.V 01.02.2020; Elsevier BV
• Subjects: Algorithms; Chaos theory; Chaotic map; Color image encryption; Color imagery; Deletion; Deoxyribonucleic acid; DNA; Encryption; Lattices; Mathematical analysis; Matrix methods; MLNCML system; Chaotic map; MLNCML system; Color image encryption; DNA
• ISSN: 0923-5965; 1879-2677
• DOI: 10.1016/j.image.2019.115670

In this paper, a new color image encryption scheme based on DNA operations and spatiotemporal chaotic system is presented. Firstly, to hide the distribution information of the plain image, we convert the plain image into three DNA matrices based on the DNA random encoding rules. Then, the DNA matrices are combined into a new matrix and is permutated by a scramble matrix generated by mixed linear-nonlinear coupled map lattices (MLNCML) system. In which, the key streams are associated with the secret keys and plain image, which can ensure our cryptosystem plain-image-dependent and improve the ability to resist known-plaintext or chosen-plaintext attacks. Thereafter, to resist statistical attacks, the scrambled matrix is decomposed into three matrices and diffused by DNA deletion-insertion operations. Finally, the three matrices are decoded based on DNA random decoding rules and recombined to three channels of the cipher image. Simulation results demonstrate that the proposed image cryptosystem has good security and can resist various potential attacks. •To hide the distribution information of the plain image, we convert the plain image into three DNA matrices based on the DNA random encoding rules.•The DNA matrices are combined into a new matrix and is permutated by a scramble matrix generated by mixed linear-nonlinear coupled map lattices (MLNCML) system. In which, the key streams are associated with the secret keys and plain image, which can ensure our cryptosystem plain-image-dependent and improve the ability to resist known-plaintext or chosen-plaintext attacks.•To resist statistical attacks, the scrambled matrix is decomposed into three matrices and diffused by DNA deletion-insertion operations. Finally, the three matrices are decoded based on DNA random decoding rules and recombined to three channels of the cipher image.