On the Image Encryption Algorithm Based on the Chaotic System, DNA Encoding, and Castle

Iqbal, Nadeem; Atif, Muhammad; Khan, Muhammad Adnan; Hanif, Muhammad; Abbas, Sagheer; Hussain, Dildar

doi:10.1109/access.2021.3106028

Cited by 36 publications

(32 citation statements)

References 54 publications

(84 reference statements)

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“…This is usually carried out since the computation of PSNR is based on the value of MSE. Nevertheless, the authors of [61] only provide PSNR values, without reporting MSE values. This is the reason behind Table 4 showing columns of N/A under the heading of [61].…”

Section: Mean Squared Errormentioning

confidence: 99%

A 3-Layer PSN for Image Encryption Utilizing Fractional-Order Chen Hyperchaotic Map and Cryptographically-Secure PRNGs

Alexan¹,

Alexan²,

Gabr³

2023

Preprint

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Image encryption is increasingly becoming an important area of research in information security and network communications, as digital images are widely used in various applications and are vulnerable to various types of attacks. In this research work, a color image cryptosystem that is based on a 3-layer permutation-substitution network (PSN) is proposed. For every layer, an encryption key and an S-box are generated and utilized. Those are based on a four-dimensional (4D) dynamical Chen system of a fractional-order, the Mersenne Twister, OpenSLL, Rule 30 Cellular Automata and Intel’s MKL. The sequential application of Shannon’s ideas of diffusion and confusion for 3 times guarantees a total distortion of any input plain image, resulting in a totally encrypted one. Apart from the excellent and comparable performance to counterpart algorithms from the literature, showcasing resistance to visual, statistical, entropy, differential, known plaintext and brute-force attacks, the proposed image cryptosystem provides an exceptionally superior performance in 2 aspects: a vast key space of 2^1658 and an average encryption rate of 3.34 Mbps. Furthermore, the proposed image cryptosystem is shown to successfully pass all the tests of the NIST SP 800 suite.

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Section: Mean Squared Errormentioning

confidence: 99%

A 3-Layer PSN for Image Encryption Utilizing Fractional-Order Chen Hyperchaotic Map and Cryptographically-Secure PRNGs

Alexan¹,

Alexan²,

Gabr³

2023

Preprint

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“…A particularly interesting proposal was also made by Iqbal et al [193], where the concept of the castle piece from the game Chess (also called the rook) was used. These authors argued that simply mixing chaos and DNA is not enough, and to more effectively scramble and confuse the pixels of the image, random movements of the castle piece were simulated on a chessboard with dimensions equivalent to the image.…”

Section: Dna Computingmentioning

confidence: 99%

Chaotic Image Encryption: State-of-the-Art, Ecosystem, and Future Roadmap

Zolfaghari

Koshiba

2022

ASI

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Recently, many researchers have been interested in the application of chaos in cryptography. Specifically, numerous research works have been focusing on chaotic image encryption. A comprehensive survey can highlight existing trends and shed light on less-studied topics in the area of chaotic image encryption. In addition to such a survey, this paper studies the main challenges in this field, establishes an ecosystem for chaotic image encryption, and develops a future roadmap for further research in this area.

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“…Chaos systems are divided into two categories, lowdimensional chaotic systems and high-dimensional chaotic systems [24][25][26][27]. Low-dimensional chaotic systems include Logistic and Tent.…”

Section: Introductionmentioning

confidence: 99%

2D Sin-Cos-Henon Map for Color Image Encryption with High Security

Cheng

Wang

Dai

et al. 2022

Journal of Applied Mathematics

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In this paper, a high security color image encryption algorithm is proposed by 2D Sin-Cos-HÃ©non (2D-SCH) system. A new two-dimensional chaotic system which is 2D-SCH. This system is hyperchaotic. The use of the 2D-SCH, a color image encryption algorithm based on random scrambling and localization diffusion, is proposed. First, the secret key is generated by SHA512 through plaintext. As the initial value of the 2D-SCH system, the secret key is used to generate chaotic sequences. Then, the random scrambling is designed based on chaotic sequences. Finally, a pair of initial points is generated by the secret key; the image diffuses around this point. The ciphertext is obtained by a double encryption. Different from the traditional encryption algorithm, this paper encrypts three channels of color image simultaneously, which greatly improves the security of the algorithm. Simulation results show that the algorithm can resist various attacks.

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On the Image Encryption Algorithm Based on the Chaotic System, DNA Encoding, and Castle

Cited by 36 publications

References 54 publications

A 3-Layer PSN for Image Encryption Utilizing Fractional-Order Chen Hyperchaotic Map and Cryptographically-Secure PRNGs

A 3-Layer PSN for Image Encryption Utilizing Fractional-Order Chen Hyperchaotic Map and Cryptographically-Secure PRNGs

Chaotic Image Encryption: State-of-the-Art, Ecosystem, and Future Roadmap

2D Sin-Cos-Henon Map for Color Image Encryption with High Security

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