Your search keyword '"Aslan, Heba K."' showing total 3 results

1. Lightweight Computational Complexity Stepping Up the NTRU Post-Quantum Algorithm Using Parallel Computing.

Author

Elkabbany, Ghada Farouk, Ahmed, Hassan I. Sayed, Aslan, Heba K., Cho, Young-Im, and Abdallah, Mohamed S.

Subjects

PARALLEL programming, PARALLEL algorithms, COMPUTATIONAL complexity, CRYPTOGRAPHY, POLYNOMIAL rings, POLYNOMIAL time algorithms, PUBLIC key cryptography

Abstract

The Nth-degree Truncated polynomial Ring Unit (NTRU) is one of the famous post-quantum cryptographic algorithms. Researchers consider NTRU to be the most important parameterized family of lattice-based public key cryptosystems that has been established to the IEEE P1363 standards. Lattice-based protocols necessitate operations on large vectors, which makes parallel computing one of the appropriate solutions to speed it up. NTRUEncrypt operations contain a large amount of data that requires many repetitive arithmetic operations. These operations make it a strong candidate to take advantage of the high degree of parallelism. The main costly operation that is repeated in all NTRU algorithm steps is polynomial multiplication. In this work, a Parallel Post-Quantum NTRUEncrypt algorithm called PPQNTRUEncrypt is proposed. This algorithm exploits the capabilities of parallel computing to accelerate the NTRUEncrypt algorithm. Both analytical and Apache Spark simulation models are used. The proposed algorithm enhanced the NTRUEncrypt algorithm by approximately 49.5%, 74.5%, 87.6%, 92.5%, 93.4%, and 94.5%, assuming that the number of processing elements is 2, 4, 8, 12, 16, and 20 respectively. [ABSTRACT FROM AUTHOR]

Published

2024

2. A Survey on Parameters Affecting MANET Performance.

Author

Eltahlawy, Ahmed M., Aslan, Heba K., Abdallah, Eslam G., Elsayed, Mahmoud Said, Jurcut, Anca D., and Azer, Marianne A.

Subjects

AD hoc computer networks, INFRASTRUCTURE (Economics), TELECOMMUNICATION systems, DATA packeting, NETWORK performance, COMMUNICATION infrastructure

Abstract

A mobile ad hoc network (MANET) is an infrastructure-less network where mobile nodes can share information through wireless links without dedicated hardware that handles the network routing. MANETs' nodes create on-the-fly connections with each other to share information, and they frequently join and leave MANET during run time. Therefore, flexibility in MANETs is needed to be able to handle variations in the number of existing network nodes. An effective routing protocol should be used to be able to route data packets within this dynamic network. Lacking centralized infrastructure in MANETs makes it harder to secure communication between network nodes, and this lack of infrastructure makes network nodes vulnerable to harmful attacks. Testbeds might be used to test MANETs under specific conditions, but researchers prefer to use simulators to obtain more flexibility and less cost during MANETs' environment setup and testing. A MANET's environment is dependent on the required scenario, and an appropriate choice of the used simulator that fulfills the researcher's needs is very important. Furthermore, researchers need to define the simulation parameters and the other parameters required by the used routing protocol. In addition, if the MANET's environment handles some conditions where malicious nodes perform network attacks, the parameters affecting the MANET from the attack perspective need to be understood. This paper collects environmental parameters that might be needed to be able to set up the required environment. To be able to evaluate the network's performance under attack, different environmental parameters that evaluate the overall performance are also collected. A survey of the literature contribution is performed based on 50 recent papers. Comparison tables and statistical charts are created to show the literature contribution and the used parameters within the scope of the collected papers of our survey. Results show that the NS-2 simulator is the most popular simulator used in MANETs. [ABSTRACT FROM AUTHOR]

Published

2023

3. Anomaly Detection of Zero-Day Attacks Based on CNN and Regularization Techniques.

Author

Ibrahim Hairab, Belal, Aslan, Heba K., Elsayed, Mahmoud Said, Jurcut, Anca D., and Azer, Marianne A.

Subjects

ANOMALY detection (Computer security), DENIAL of service attacks, CONVOLUTIONAL neural networks, MACHINE learning, DATA security, INTRUSION detection systems (Computer security)

Abstract

The rapid development of cyberattacks in the field of the Internet of things (IoT) introduces new security challenges regarding zero-day attacks. Intrusion-detection systems (IDS) are usually trained on specific attacks to protect the IoT application, but the attacks that are yet unknown for IDS (i.e., zero-day attacks) still represent challenges and concerns regarding users' data privacy and security in those applications. Anomaly-detection methods usually depend on machine learning (ML)-based methods. Under the ML umbrella are classical ML-based methods, which are known to have low prediction quality and detection rates with regard to data that it has not yet been trained on. DL-based methods, especially convolutional neural networks (CNNs) with regularization methods, address this issue and give a better prediction quality with unknown data and avoid overfitting. In this paper, we evaluate and prove that the CNNs have a better ability to detect zero-day attacks, which are generated from nonbot attackers, compared to classical ML. We use classical ML, normal, and regularized CNN classifiers (L1, and L2 regularized). The training data consists of normal traffic data, and DDoS attack data, as it is the most common attack in the IoT. In order to give the full picture of this evaluation, the testing phase of those classifiers will include two scenarios, each having data with different attack distribution. One of these is the backdoor attack, and the other is the scanning attack. The results of the testing proves that the regularized CNN classifiers still perform better than the classical ML-based methods in detecting zero-day IoT attacks. [ABSTRACT FROM AUTHOR]

Published

2023