Color image encryption based on a square-term enhanced 4D chaotic system

Ping Gao; Tianxiu Lu; Jiahua Dong; Ping Gao; Tianxiu Lu; Jiahua Dong

doi:10.3934/era.2026202

Electronic Research Archive

2026, Volume 34, Issue 7: 4577-4610. doi: 10.3934/era.2026202

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Research article

Color image encryption based on a square-term enhanced 4D chaotic system

1.
College of Mathematics and Statistics, Sichuan University of Science and Engineering, Zigong 643000, China
2.
Brewing Science and Technology Key Laboratory of Sichuan Province, Zigong 643000, China

Received: 17 March 2026 Revised: 05 May 2026 Accepted: 07 May 2026 Published: 28 May 2026

Chaotic systems confer distinct advantages for image encryption due to their remarkable responsiveness to initial parameters, inherent unpredictability, and characteristics of pseudo-randomness. However, many existing chaos-based image encryption schemes still suffer from limitations such as narrow chaotic parameter intervals, insufficient trajectory uniformity, and inadequate diffusion depth, which may weaken the randomness of generated sequences and reduce encryption robustness. To address these issues, a square-term enhanced four-dimensional chaotic system was constructed, and a color image encryption scheme integrating hierarchical scrambling and symmetric bidirectional diffusion was developed. Dynamic analyses, including phase portraits, bifurcation diagrams, maximum Lyapunov exponents, time-series distribution, and complexity evaluation, indicate that the proposed system exhibits a broad chaotic interval, strong initial-value sensitivity, and improved trajectory uniformity. It can well-adapt to the image encryption requirements of different categories. Simulation experiments conducted using a variety of test images indicate that the encryption scheme offers an adequately large key space, with pixel correlation measured at less than 0.03, information entropy exceeding 7.9974, and robust resistance to differential attacks. The computed mean values for number of pixels change rate (NPCR) and unified average changing intensity (UACI) were found to be 99.6073% and 33.4626%, respectively, demonstrating a strong alignment with the optimal benchmarks. The algorithm achieves competitive performance in terms of efficiency and security, can effectively resist common attacks, and is suitable for the secure transmission and storage of sensitive images.
- four-dimensional chaotic system,
- dynamic analysis,
- two-level scrambling,
- multidirectional random diffusion,
- image encryption
Citation: Ping Gao, Tianxiu Lu, Jiahua Dong. Color image encryption based on a square-term enhanced 4D chaotic system[J]. Electronic Research Archive, 2026, 34(7): 4577-4610. doi: 10.3934/era.2026202

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Abstract

Chaotic systems confer distinct advantages for image encryption due to their remarkable responsiveness to initial parameters, inherent unpredictability, and characteristics of pseudo-randomness. However, many existing chaos-based image encryption schemes still suffer from limitations such as narrow chaotic parameter intervals, insufficient trajectory uniformity, and inadequate diffusion depth, which may weaken the randomness of generated sequences and reduce encryption robustness. To address these issues, a square-term enhanced four-dimensional chaotic system was constructed, and a color image encryption scheme integrating hierarchical scrambling and symmetric bidirectional diffusion was developed. Dynamic analyses, including phase portraits, bifurcation diagrams, maximum Lyapunov exponents, time-series distribution, and complexity evaluation, indicate that the proposed system exhibits a broad chaotic interval, strong initial-value sensitivity, and improved trajectory uniformity. It can well-adapt to the image encryption requirements of different categories. Simulation experiments conducted using a variety of test images indicate that the encryption scheme offers an adequately large key space, with pixel correlation measured at less than 0.03, information entropy exceeding 7.9974, and robust resistance to differential attacks. The computed mean values for number of pixels change rate (NPCR) and unified average changing intensity (UACI) were found to be 99.6073% and 33.4626%, respectively, demonstrating a strong alignment with the optimal benchmarks. The algorithm achieves competitive performance in terms of efficiency and security, can effectively resist common attacks, and is suitable for the secure transmission and storage of sensitive images.

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