Robust Security With Strong Authentication in Mobile Cloud Computing Based on Trefoil Congruity Framework

Abstract

Mobile cloud computing (MCC) initially draws on cloud and mobile computing principles, where it focuses on wireless networks to provide mobile users with rich computing services. In the modern era, the sharing of secured large-scale data is the major challenging task. However, problems continue to be resolved such that the omnipresent usage and use of mobile cloud computing are feasible. Some of the challenges include security, lossless back-up and data recovery, and computational complexity. To deal with this scenario, a unique combination of the trefoil congruity framework is proposed to secure a privacy-preserving user consent solution by using the backup method to store and recover a huge amount of data. Quantum key fibo privacy approach (QKFPA) encrypts and decrypts the data using the fibonacci chain-leaning matrix along with quantum computation to provide security while transmitting/unloading user information. Consecutively, high-security distribution and rake technology (HSDRT) is enhanced to block the inside attackers and ensures retrieval of saved data without any loss. Once the storage is enhanced, data access is highly secured through the emperor-imperial technique, which generates an imperial label between mobile users and cloud server through the selection of emperor node. The outcome of the work offers great fortification for cyber threats, authentication, and lossless retrieval of data in MCCs.