Everyone desires to avail online services provided by different service providers securely, efficiently, and effectively. In this regard, security is still a significant concern for them. However, no one guarantees secure communication by browsing different applications remotely. To ensure confidentiality, authorization, availability, nonrepudiation, and removing eavesdropping, without a robust authentication scheme, nothing will go right. Therefore, we attempted to design a robust and privacy-preserving authentication scheme for end-users to securely access public cloud servers’ services remotely without losing performance. Our proposed scheme security has been evaluated formally using the random oracle model (ROM) and ProVerif2.03 and informally using proposition and discussion. At the same time, the performance metric has been analyzed by considering the scheme’s computation and communication costs. Upon comparing the proposed scenario with state-of-the-artwork, it has been demonstrated that the scheme is much better in terms of security and performance, as these are contradicting metrics, and the change in one conversely affects the other.
Named data networking (NDN) is an emerging technology. It was designed to eliminate the dependency of IP addresses in the hourglass model. Mobility is a key concern of the modern Internet architecture, even though the NDN architecture has solved the consumer mobility. That is, the consumer can rerequest the desired data contents, while the producer mobility remains as an issue in the NDN architecture. This paper focuses on the issue of producer mobility and proposes the cluster-based device mobility management scheme, which uses the cluster heads to solve the producer mobility issue in NDN. In the proposed scheme, a cluster head has all information of its attached devices. A cluster head updates the routes, when a device moves to the new access router by sending all the attachment information. The proposed scheme is evaluated and compared with the existing scheme by using the ndnSIM simulation. From the results, we see that the proposed scheme can decrease the numbers of interest packets in the network, compared with the existing scheme.
Public cloud computing has become increasingly popular due to the rapid advancements in communication and networking technology. As a result, it is widely used by businesses, corporations, and other organizations to boost the productivity. However, the result generated by millions of network-enabled IoT devices and kept on the public cloud server, as well as the latency in response and safe transmission, are important issues that IoT faces when using the public cloud computing. These concerns and obstacles can only be overcome by designing a robust mutual authentication and secure cross-verification mechanism. Therefore, we have attempted to design a cryptographic protocol based on a simple hash function, xor operations, and the exchange of random numbers. The security of the proposed protocol has formally been verified using the ROR model, ProVerif2.03, and informally using realistic discussion. In contrast, the performance metrics have been analyzed by looking into the security feature, communication, and computation costs. To sum it up, we have compared our proposed security mechanism with the state-of-the-art protocols, and we recommend it to be effectively implemented in the public cloud computing environment.
Public cloud computing provides a variety of services to consumers via high-speed internet. The consumer can access these services anytime and anywhere on a balanced service cost. Many traditional authentication protocols are proposed to secure public cloud computing. However, the rapid development of high-speed internet and organizations' race to develop quantum computers is a nightmare for existing authentication schemes. These traditional authentication protocols are based on factorization or discrete logarithm problems. As a result, traditional authentication protocols are vulnerable in the quantum computing era. Therefore, in this article, we have proposed an authentication protocol based on the lattice technique for public cloud computing to resist quantum attacks and prevent all known traditional security attacks. The proposed lattice-based authentication protocol is provably secure under the Real-Or-Random (ROR) model. At the same time, the result obtained during the experiments proved that our protocol is lightweight compared to the existing lattice-based authentication protocols, as listed in the performance analysis section. The comparative analysis shows that the protocol is suitable for practical implementation in a quantum-based environment.
Through the broad usage of cloud computing and the extensive utilization of next-generation public clouds, people can share valuable information worldwide via a wireless medium. Public cloud computing is used in various domains where thousands of applications are connected and generate numerous amounts of data stored on the cloud servers via an open network channel. However, open transmission is vulnerable to several threats, and its security and privacy are still a big challenge. Some proposed security solutions for protecting next-generation public cloud environments are in the literature. However, these methods may not be suitable for a wide range of applications in a next-generation public cloud environment due to their high computing and communication overheads because if security protocol is strengthened, it inversely impacts performance and vice versa. Furthermore, these security frameworks are vulnerable to several attacks, such as replay, denial-of-service (DoS), insider, server spoofing, and masquerade, and also lack strong user anonymity and privacy protection for the end user. Therefore, this study aims to design an elliptic curve cryptographic (ECC) based data access control protocol for a public cloud environment. The security mechanism of the proposed protocol can be verified using BAN (Burrows-Abadi-Needham) logic and ProVerif 2.03, as well as informally using assumptions and pragmatic illustration. In contrast, in the performance analysis section, we have considered the parameters such as the complexity of storage overheads, communication, and computation time. As per the numerical results obtained in the performance analysis section, the proposed protocol is lightweight, robust, and easily implemented in a practical next-generation cloud computing environment.
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