基于位平面-块置乱的图像加密算法安全性分析

doi:10.3969/j.issn.0255-8297.2019.05.005

Abstract

Abstract: In this paper, a known plaintext attack method based on the root mean square (RMS) of image block is proposed for ATBEM. Firstly, the scrambling sequence of bit planes is estimated to restore the original pixel value by using the invariant distribution ratio of 0 and 1 of plaintext images before and after encryption. Then, according to the characteristics of block scrambling and intra-block scrambling, which keeps the pixel value constant, a root mean square (RMS) feature of image block is defined to find and estimate the block scrambling matrix. The security performance of image block scrambling encryption is analyzed and discussed. The analysis results show that the smoother the image is, the smaller the blocks are, the more plaintext logarithms are needed to crack, and the more difficult the known plaintext attack is. Experimental results verify that the more texture the image is, the better the attack effect is. Under the condition of 2×2 block size, the attacker can crack more than 50% of the ciphertext image content with only one pair of known plaintext-ciphertext pairs known. And ATBEM encryption algorithm is difficult to resist the proposed known plaintext attack.

Key words: reversible data hiding in encrypted image, image block root mean square (RMS), known plaintext attack, bit plane-block scrambling

CLC Number:

TP391

QU Lingfeng, CHEN fan, HE Hongjie, YUAN yuan. Security Analysis of Image Encryption Algorithm Based on Bit Plane-Pixel Block Scrambling[J]. Journal of Applied Sciences, 2019, 37(5): 631-642.

References

[1] Shi Y Q, Li X L, Zhang X P, et al. Reversible data hiding:advances in the past two decades[J]. IEEE Access, 2016(4):3210-3237.
[2] Ma K, Zhang W M, Zhao X F, et al. Reversible data hiding in encrypted images by reserving room before encryption[J]. IEEE Transactions on Information Forensics and Security, 2013, 8(3):553-562.
[3] Xu D, Wang R D. Separable and error-free reversible data hiding in encrypted images[J]. Signal Processing, 2016, 123:9-21.
[4] Thaison N, Chang C, Chang W C. High capacity reversible data hiding scheme for encrypted images[J]. Signal Processing:Image Communication, 2016, 44:84-91.
[5] Cao X, Du L, Wei X, et al. High capacity reversible data hiding in encrypted images by patchlevel sparse representation[J]. IEEE Transactions on Cybernetics, 2016, 46(5):1132-1143.
[6] Yi S, Zhou Y C. Binary-block embedding for reversible data hiding in encrypted images[J]. Signal Processing, 2017, 133:40-51.
[7] Chen Y, Yan S, He H, et al. Secure reversible data hiding in encrypted images based on MSB-flip prediction:China, 201810174576.8[P]. 2018-03-02.
[8] Zhang X. Separable reversible data hiding in encrypted image[J]. IEEE Transactions on Information Forensics and Security, 2012, 7(2):826-832.
[9] Yin Z, Luo B, Hong W. Separable and error-free reversible data hiding in encrypted image with high payload[J]. The Scientific World Journal, 2014(1):1-8.
[10] Yin Z X, Abel A, Zhang X P, et al. Reversible data hiding in encrypted image based on block histogram shifting[J]. IEEE International Conference on Acoustics, Speech and Signal Processing, 2016:2129-2133.
[11] Yin Z X, Abel A, Tang J, et al. Reversible data hiding in encrypted images based on multilevel encryption and block histogram modification[J]. Multimedia Tools and Applications, 2017, 76(3):1-22.
[12] Zhou J T, Sun W W, Dong L, et al. Secure reversible image data hiding over encrypted domain via key modulation[J]. IEEE Transactions on Circuits and Systems for Video Technology, 2016, 26(3):441-452.
[13] Qian Z, Zhang X. Reversible data hiding in encrypted images with distributed source encoding[J]. IEEE Transactions on Circuits and Systems for Video Technology, 2016, 26(4):636-646.
[14] Qin C, He Z, Luo X, et al. Reversible data hiding in encrypted image with separable capability and high embedding capacity[J]. Information Sciences, 2018, 465:285-304.
[15] Qin C, Zhang W, Cao F, et al. Separable reversible data hiding in encrypted images via adaptive embedding strategy with block selection[J]. Signal Processing, 2018, 153:109-122.
[16] Liu Z, Pun C. Reversible data-hiding in encrypted images by redundant space transfer[J]. Information Sciences, 2018, 433(1):188-203.
[17] Khelifi F. On the security of a stream cipher in reversible data hiding schemes operating in the encrypted domain[J]. Signal Processing, 2018, 143:336-345.
[18] Li S J, Li C Q, Chen G R, et al. A general quantitative cryptanalysis of permutation-only multimedia ciphers against plaintext attacks[J]. Signal Processing:Image Communication, 2008, 23(3):212-223.
[19] Li C, Lo K T. Optimal quantitative cryptanalysis of permutation-only multimedia ciphers against plaintext attacks[J]. Signal Processing:Image Communication, 2009, 91(4):949-954.
[20] Jolfaei A, Wu X, Muthukkumarasamy V. On the security of permutation-only image encryption schemes[J]. IEEE Transactions on Information Forensics and Security, 2016, 11(2):235-246.
[21] Zhang W, Wong K W, Yu H, et al. A symmetric color image encryption algorithm using the intrinsic features of bit distributions[J]. Communications in Nonlinear Science and Numerical Simulation, 2013, 18(3):584-600.

Security Analysis of Image Encryption Algorithm Based on Bit Plane-Pixel Block Scrambling

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	YAO Rujing, YANG Lei, YANG Tao, HU Yingxin, TIAN Qiang, WU Ou. Analysis for Psychological Scale Big Data Based on Improved Ising Model [J]. Journal of Applied Sciences, 2020, 38(3): 339-352.
[2]	JIANG Qinyin, ZHANG Xi. Topic-Specific Assessment Approach for Social Network Influence Evaluation [J]. Journal of Applied Sciences, 2020, 38(3): 353-366.
[3]	ZHANG Tongtong, DONG Junyu, ZHAO Haoran, LI Qiong, SUN Xin. Lightweight Phytoplankton Detection Network Based on Knowledge Distillation [J]. Journal of Applied Sciences, 2020, 38(3): 367-376.
[4]	WEI Ziyang, ZHAO Zhihong, ZHAO Jingjiao. Improved Faster R-CNN Algorithm and Its Application on Vehicle Detection [J]. Journal of Applied Sciences, 2020, 38(3): 377-387.
[5]	SUN Ronghai, SHI Linfu, YU Chunqiang, LAO Huan, TANG Zhenjun. Random Interpolation Method for Data Hiding in Encrypted Images [J]. Journal of Applied Sciences, 2020, 38(3): 419-430.
[6]	WANG Daqian, CUI Rongyi, JIN Jingxuan. Text Detection in Natural Scene Based on Visual Attention Model and Multi-scale MSER [J]. Journal of Applied Sciences, 2020, 38(3): 496-506.
[7]	YANG Gaoqiang, LI Sheng, ZHANG Xinpeng. Altered Fingerprint Detection Based on Orientation Field [J]. Journal of Applied Sciences, 2019, 37(6): 775-782.
[8]	YU Shuzhen, OU Qiaofeng, XIONG Bangshu, CHEN Yaofeng. A Calibration Method Based on Defocused Image for Stereo Vision Sensor with Large FOV [J]. Journal of Applied Sciences, 2019, 37(6): 795-805.
[9]	CUI Sanshuai, MAO Maoyu, LIN Xiaodan, KANG Xiangui. Survey on Analysis and Applications of Electric Network Frequency (ENF) Signals in Image and Video [J]. Journal of Applied Sciences, 2019, 37(5): 573-589.
[10]	LIU Wei, ZHANG Wanling, XIANG Shijun. Face Anti-spoofing Based on LBP, Multilayer DCT and CNN [J]. Journal of Applied Sciences, 2019, 37(5): 609-617.
[11]	ZHAO Yan, ZHOU Xiaowei, SHEN Qi. Compact Image Hashing Algorithm Based on Opposite Color and Salient Region [J]. Journal of Applied Sciences, 2019, 37(5): 691-703.
[12]	ZHANG Yongsheng, TIAN Huawei, XIAO Yanhui, HAO Xinze, ZHANG Mingwang. PRNU Extraction Algorithm Based on Trilateral Weighted Sparse Coding Model [J]. Journal of Applied Sciences, 2019, 37(5): 704-710.
[13]	ZHU Yiming, CHEN Fan, HE Hongjie, CHEN Hongyou. Orthogonal GAN Information Hiding Model Based on Secret Information Driven [J]. Journal of Applied Sciences, 2019, 37(5): 721-732.
[14]	WANG Junxiang, MAO Ningxiong, ZHAO Yi, WANG Chuntao. Large Color Image Based High-Performance Reversible Data Hiding Hcheme for Various Capacities [J]. Journal of Applied Sciences, 2019, 37(5): 744-760.
[15]	QIN Zhen, DAI Xiubin, XIE Lizhe. Anatomical Landmark Localization in Lateral Cephalograms by Using Two-Layer Regression Forests [J]. Journal of Applied Sciences, 2019, 37(4): 481-489.