A New Trust Framework for E-Government in Cloud of Things

The concept of Cloud of Things becomes important for each e-government, facilitating its way of work, increasing its productivity and all that leading to cost savings. It will likely have a significant impact on the e-governments in the future. E-government diversity goals face many challenges. Trust is a major challenge when deploying Cloud of Things in e-government. In this paper, a new trust framework is proposed that supports trust between Internet of Things devices interconnected to the Cloud in order to support e-government services to be delivered in trusted manner. The proposed framework has been applied to a use case study to ensure the trustworthiness of the proposed framework in a real mission. The results show that the proposed trust framework is useful to ensuring a trust environment for Cloud of Things in order to continue providing and gathering data needed to provide services to users through the E-government services

Multi-round encryption for COVID-19 data using the DNA key

The need for a reliable and fast encryption algorithm to encrypt medical data for patients is an extremely important topic to be considered especially during pandemic times such as the pandemic COVID-19. This pandemic forced governments and healthcare institutions to monitor COVID-19 patients. All the patient's data or records are also shared among healthcare researchers to be used to help them find vaccines or cures for this pandemic. Therefore, protecting such data (images, text) or records face an everincreasing number of risks. In this paper, a novel multi-round encryption algorithm based on deoxyribonucleic acid (DNA) is proposed. The significance of the proposed algorithm comes from using a different random key to perform simple and fast encryption operations on multiple rounds to achieve a high level of confusion and diffusion effects in encrypted data. Experiments were conducted using a set of datasets of various types such as Excel sheets, images, and database tables. The experiments were conducted to test the performance and security level of the proposed encryption algorithm against well-known algorithms such as data encryption standard (DES) and advanced encryption standard (AES). The experiments show an outstanding performance regarding the encryption time, key size, information entropy, and the avalanche effects