Medical Images Encryption Based on Adaptive-Robust Multi-Mode Synchronization of Chen Hyper-Chaotic Systems
Metadata
Show full item recordEditorial
MDPI
Materia
Medical images Encryption Multi-mode synchronization Robust control Time varying Lyapunov stability
Date
2021Referencia bibliográfica
Javan, A.A.K.; Jafari, M.; Shoeibi, A.; Zare, A.; Khodatars, M.; Ghassemi, N.; Alizadehsani, R.; Gorriz, J.M. Medical Images Encryption Based on Adaptive-Robust Multi-Mode Synchronization of Chen Hyper-Chaotic Systems. Sensors 2021, 21, 3925. https://doi.org/10.3390/ s21113925
Sponsorship
MINECO/ FEDER under the RTI2018-098913-B100 CV20-45250 and A-TIC- 080-UGR18 projectsAbstract
In this paper, a novel medical image encryption method based on multi-mode synchronization of hyper-chaotic systems is presented. The synchronization of hyper-chaotic systems is of
great significance in secure communication tasks such as encryption of images. Multi-mode synchronization is a novel and highly complex issue, especially if there is uncertainty and disturbance. In
this work, an adaptive-robust controller is designed for multimode synchronized chaotic systems
with variable and unknown parameters, despite the bounded disturbance and uncertainty with a
known function in two modes. In the first case, it is a main system with some response systems,
and in the second case, it is a circular synchronization. Using theorems it is proved that the two
synchronization methods are equivalent. Our results show that, we are able to obtain the convergence
of synchronization error and parameter estimation error to zero using Lyapunov’s method. The
new laws to update time-varying parameters, estimating disturbance and uncertainty bounds are
proposed such that stability of system is guaranteed. To assess the performance of the proposed
synchronization method, various statistical analyzes were carried out on the encrypted medical
images and standard benchmark images. The results show effective performance of the proposed
synchronization technique in the medical images encryption for telemedicine application.