TY - JOUR
T1 - DeepSLM
T2 - Speckle-Licensed Modulation via Deep Adversarial Learning for Authorized Optical Encryption and Decryption
AU - Huang, Haofan
AU - Zhao, Qi
AU - Li, Huanhao
AU - Zheng, Yuandong
AU - Yu, Zhipeng
AU - Zhong, Tianting
AU - Cheng, Shengfu
AU - Woo, Chi Man
AU - Gao, Yi
AU - Liu, Honglin
AU - Zheng, Yuanjin
AU - Tian, Jie
AU - Lai, Puxiang
N1 - Publisher Copyright:
© 2024 The Author(s). Advanced Intelligent Systems published by Wiley-VCH GmbH.
PY - 2024/11
Y1 - 2024/11
N2 - Optical encryption is pivotal in information security, offering parallel processing, speed, and robust security. The simplicity and compatibility of speckle-based cryptosystems have garnered considerable attention. Yet, the predictable statistical distribution of speckle optical fields’ characteristics can invite statistical attacks, undermining these encryption methods. The proposed solution, a deep adversarial learning-based speckle modulation network (DeepSLM), disrupts the strong intercorrelation of speckle grains. Utilizing the unique encoding properties of speckle patterns, DeepSLM facilitates license editing within the modulation phase, pioneering a layered authentication encryption system. Our empirical studies confirm DeepSLM's superior performance on key metrics. Notably, the testing dataset reveals an average Pearson correlation coefficient above 0.97 between decrypted images and their original counterparts for intricate subjects like human faces, attesting to the method's high fidelity. This innovation marries adjustable modification, optical encryption, and deep learning to enforce tiered data access control, charting new paths for creating user-specific access protocols.
AB - Optical encryption is pivotal in information security, offering parallel processing, speed, and robust security. The simplicity and compatibility of speckle-based cryptosystems have garnered considerable attention. Yet, the predictable statistical distribution of speckle optical fields’ characteristics can invite statistical attacks, undermining these encryption methods. The proposed solution, a deep adversarial learning-based speckle modulation network (DeepSLM), disrupts the strong intercorrelation of speckle grains. Utilizing the unique encoding properties of speckle patterns, DeepSLM facilitates license editing within the modulation phase, pioneering a layered authentication encryption system. Our empirical studies confirm DeepSLM's superior performance on key metrics. Notably, the testing dataset reveals an average Pearson correlation coefficient above 0.97 between decrypted images and their original counterparts for intricate subjects like human faces, attesting to the method's high fidelity. This innovation marries adjustable modification, optical encryption, and deep learning to enforce tiered data access control, charting new paths for creating user-specific access protocols.
KW - authorized encryption and decryption
KW - deep learning
KW - optical speckle
KW - privacy protection
KW - wavefront shaping
UR - https://www.scopus.com/pages/publications/85205234472
U2 - 10.1002/aisy.202400150
DO - 10.1002/aisy.202400150
M3 - 文章
AN - SCOPUS:85205234472
SN - 2640-4567
VL - 6
JO - Advanced Intelligent Systems
JF - Advanced Intelligent Systems
IS - 11
M1 - 2400150
ER -