Exploiting Newly Designed Fractional-Order 3D Lorenz Chaotic System and 2D Discrete Polynomial Hyper-Chaotic Map for High-Performance Multi-Image Encryption

Feng, Wei; Wang, Quanwen; Liu, Hui; Ren, Yu; Zhang, Junhao; Zhang, Shubo; Qian, Kun; Wen, Heping

doi:10.3390/fractalfract7120887

Cited by 29 publications

(13 citation statements)

References 44 publications

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“…In the proposed cryptosystem, the encrypted ciphertext comes from the output of the attention module. The key space [41,42,45] can be infinite because either the two sequences of single-pixel measurements or the input cryptographic key sequence are random with unlimited dynamic range.…”

Section: Optical Experiments Resultsmentioning

confidence: 99%

“…Therefore, the forward propagation process of this module can also be regarded as the encryption of these three input vectors. Based on this concept, this paper proposes a physically driven neural network SPI encryption scheme using the above attention module to deal with multi-image encryption tasks [39][40][41][42]. We let the two vectors of the attention module be taken from single-pixel measurements that correspond to two different object images and set the sequence of cryptographic keys as the third vector.…”

Section: Introductionmentioning

confidence: 99%

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Optical Encryption Using Attention-Inserted Physics-Driven Single-Pixel Imaging

Yu,

Wang,

Shang

2024

Sensors

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Optical encryption based on single-pixel imaging (SPI) has made great advances with the introduction of deep learning. However, the use of deep neural networks usually requires a long training time, and the networks need to be retrained once the target scene changes. With this in mind, we propose an SPI encryption scheme based on an attention-inserted physics-driven neural network. Here, an attention module is used to encrypt the single-pixel measurement value sequences of two images, together with a sequence of cryptographic keys, into a one-dimensional ciphertext signal to complete image encryption. Then, the encrypted signal is fed into a physics-driven neural network for high-fidelity decoding (i.e., decryption). This scheme eliminates the need for pre-training the network and gives more freedom to spatial modulation. Both simulation and experimental results have demonstrated the feasibility and eavesdropping resistance of this scheme. Thus, it will lead SPI-based optical encryption closer to intelligent deep encryption.

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Section: Optical Experiments Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optical Encryption Using Attention-Inserted Physics-Driven Single-Pixel Imaging

Yu,

Wang,

Shang

2024

Sensors

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“…In [20], an innovative approach to the encryption of colour images was proposed, where the algorithm was based on extended DNA coding, the Zig-Zag transform, and a fractional-order laser system [21]. Other notable works in this area include "Achieving Superior Multi-Image Encryption Through the Use of Recently Conceived Fractional-Order 3D Lorenz Chaotic System and 2D Discrete Polynomial Hyper-Chaotic Map" [22] and "Fragmentary Fractional Order Systems: Modeling and Initialization Using the Infinite State Representation" [23].…”

Section: Introductionmentioning

confidence: 99%

Real-Time Synchronisation of Multiple Fractional-Order Chaotic Systems: An Application Study in Secure Communication

Nail,

Atoussi,

Saadi

et al. 2024

Fractal Fract

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In this paper, we use two Fractional-Order Chaotic Systems (FOCS)—one for the sender and one for the receiver—to determine the optimal synchronisation for a secure communication technique. With the help of the Step-By-Step Sliding-Mode Observer (SBS-SMO), this synchronisation is accomplished. An innovative optimisation method, known as the artificial Harris hawks optimisation (HHO), was employed to enhance the observer’s performance. This method eliminates the random parameter selection process and instead selects the optimal values for the observer. In a short amount of time, the secret message that could have been in the receiver portion (signal, voice, etc.) was successfully recovered using the proposed scheme. The experimental validation of the numerical results was carried out with the assistance of an Arduino microcontroller and several electronic components. In addition, the findings of the experiments were compared with the theoretical calculations, revealing a satisfactory level of agreement.

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“…Chaos is widely used and highly respected in the field of image encryption due to its unpredictability, pseudorandomness, and high sensitivity to initial values. At present, a variety of encryption methods have been proposed, including quantum cipher [13][14][15], bit-level encryption [16][17][18], discrete wavelet transform [19][20][21], thumbnail-preserving encryption [22][23][24], biological coding [25][26][27], discrete cosine transform [28][29][30], Fourier transform [31][32][33], chaos theory [34][35][36][37][38][39][40] and so on [41][42][43][44][45].…”

Section: Introductionmentioning

confidence: 99%

Frequency-domain image encryption based on IWT and 3D S-box

Wen,

Feng,

Bai

et al. 2024

Phys. Scr.

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Most of the existing spatial domain image encryption techniques suffer from the difficulty of resisting cryptographic attacks. For this reason, this paper proposes a frequency-domain based digital image encryption scheme by combining Integer Wavelet Transform (IWT), three-dimensional S-box and chaotic system. Firstly, the plaintext image is decomposed into different frequency subbands by IWT to map the digital image from spatial domain to frequency domain. Second, the plaintext hash value is selected as the dynamic key, and dynamic chaotic pseudo-random sequences with associations are generated, which are used for the encryption of each module respectively. Then, a three-dimensional S-box is designed to encrypt the information-rich low-frequency information using ``bit-permutation three-dimensional S-box substitution ciphertext interleaved diffusion'', while the high-frequency information is encrypted using a lightweight ``XOR-row column permutation'' operation. Finally, the secure ciphertext for public channel transmission is obtained by the reconstruction method. the scheme of this paper, the frequency domain transformation is implemented through IWT, which enhances the ability to resist attacks. In addition, each encryption module employs a closed-loop feedback mechanism, thus the algorithm has the ability to resist plaintext attacks. Theoretical analysis and empirical results show that the algorithm has excellent numerical statistical analysis results, These findings confirm that the proposed method exhibits good confusion, diffusion, and avalanche effects and can withstand a variety of popular cryptographic attacks. Given that frequency domain picture encryption is a preferred high-security technique for safeguarding the privacy of digital photographs, it is a workable solution for practical applications.

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Exploiting Newly Designed Fractional-Order 3D Lorenz Chaotic System and 2D Discrete Polynomial Hyper-Chaotic Map for High-Performance Multi-Image Encryption

Cited by 29 publications

References 44 publications

Optical Encryption Using Attention-Inserted Physics-Driven Single-Pixel Imaging

Optical Encryption Using Attention-Inserted Physics-Driven Single-Pixel Imaging

Real-Time Synchronisation of Multiple Fractional-Order Chaotic Systems: An Application Study in Secure Communication

Frequency-domain image encryption based on IWT and 3D S-box

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