Showing total 4 results

1. B4SDC: A Blockchain System for Security Data Collection in MANETs

Author

Xiaokang Zhou, Zheng Yan, Huidong Dong, Shohei Shimizu, Gao Liu, Department of Communications and Networking, Xidian University, Shiga University, Aalto-yliopisto, and Aalto University

Subjects

blockchain, Ad hoc networks, Information Systems and Management, Spoofing attack, Computer science, Wireless ad hoc network, MANETs, Mobile computing, 02 engineering and technology, Digital signature, 0202 electrical engineering, electronic engineering, information engineering, Data collection, business.industry, Node (networking), 020206 networking & telecommunications, Mobile ad hoc network, security-related data collection, Task analysis, Collusion, incentive mechanism, 020201 artificial intelligence & image processing, business, Bitcoin, Information Systems, Computer network

Abstract

Security-related data collection is an essential part for attack detection and security measurement in Mobile Ad Hoc Networks (MANETs). A detection node (i.e., collector) should discover available routes to a collection node for data collection and collect security-related data during route discovery for determining reliable routes. However, few studies provide incentives for security-related data collection in MANETs. In this paper, we propose B4SDC, a blockchain system for security-related data collection in MANETs. Through controlling the scale of Route REQuest (RREQ) forwarding in route discovery, the collector can constrain its payment and simultaneously make each forwarder of control information (namely RREQs and Route REPlies, in short RREPs) obtain rewards as much as possible to ensure fairness. At the same time, B4SDC avoids collusion attacks with cooperative receipt reporting, and spoofing attacks by adopting a secure digital signature. Based on a novel Proof-of-Stake consensus mechanism by accumulating stakes through message forwarding, B4SDC not only provides incentives for all participating nodes, but also avoids forking and ensures high efficiency and real decentralization. We analyze B4SDC in terms of incentives and security, and evaluate its performance through simulations. The thorough analysis and experimental results show the efficacy and effectiveness of B4SDC.

Published

2022

2. Enhanced Message Replication Technique for DTN Routing Protocols

Author

Siham Hasan, Meisam Sharifi Sani, Saeid Iranmanesh, Ali H. Al-Bayatti, Sarmadullah Khan, and Raad Raad

Subjects

Electrical and Electronic Engineering, Biochemistry, Instrumentation, delay-tolerant network, network congestion, DTN routing, congestion control, wireless networks, ad hoc networks, Atomic and Molecular Physics, and Optics, Analytical Chemistry

Abstract

Delay-tolerant networks (DTNs) are networks where there is no immediate connection between the source and the destination. Instead, nodes in these networks use a store–carry–forward method to route traffic. However, approaches that rely on flooding the network with unlimited copies of messages may not be effective if network resources are limited. On the other hand, quota-based approaches are more resource-efficient but can have low delivery rates and high delivery delays. This paper introduces the Enhanced Message Replication Technique (EMRT), which dynamically adjusts the number of message replicas based on a node’s ability to quickly disseminate the message. This decision is based on factors such as current connections, encounter history, buffer size history, time-to-live values, and energy. The EMRT is applied to three different quota-based protocols: Spray and Wait, Encounter-Based Routing (EBR), and the Destination-Based Routing Protocol (DBRP). The simulation results show that applying the EMRT to these protocols improves the delivery ratio, overhead ratio, and latency average. For example, when combined with Spray and Wait, EBR, and DBRP, the delivery probability is improved by 13%, 8%, and 10%, respectively, while the latency average is reduced by 51%, 14%, and 13%, respectively.

Published

2023

3. Game-Theory-Based Multimode Routing Protocol for Internet of Things

Author

Shafiullah Khan, Muhammad Muneer Umar, Chunhua Jin, Shaozhang Xiao, Zeeshan Iqbal, and Noha Alnazzawi

Subjects

Computer Networks and Communications, Hardware and Architecture, Control and Systems Engineering, Signal Processing, Electrical and Electronic Engineering, IoT, multimode routing, ad hoc networks, heterogeneous networks, routing protocols

Abstract

Various routing protocols have been proposed for ad hoc networks such as the Internet of Things (IoT). Most of the routing protocols introduced for IoT are specific to applications and networks. In the current literature, it is essential to configure all the network nodes with a single proposed protocol. Moreover, it is also possible for a single IoT network to consist of different kinds of nodes. Two or more IoT networks can also be connected to create a bigger heterogeneous network. Such networks may need various routing protocols with some gateway nodes installed. The role of gateway nodes should not be limited to the interconnection of different nodes. In this paper, a multi-mode hybrid routing mechanism is proposed that can be installed on all or a limited number of nodes in a heterogenous IoT network. The nodes configured with the proposed protocols are termed smart nodes. These nodes can be used to connect multiple IoT networks into one. Furthermore, a game-theory-based model is proposed that is used for intercommunication among the smart nodes to gain optimal efficiency. Various performance matrices are assessed under different network scenarios. The simulation results show that the proposed mechanism outperforms in broader heterogeneous IoT networks with diverse nodes.

Published

2022

4. Maintaining Effective Node Chain Connectivity in the Network with Transmission Power of Self-Arranged AdHoc Routing in Cluster Scenario

Author

Kiruthiga Devi Murugavel, Parthasarathy Ramadass, Rakesh Kumar Mahendran, Arfat Ahmad Khan, Mohd Anul Haq, Sultan Alharby, and Ahmed Alhussen

Subjects

ad hoc networks, cluster, self-mending, traffic density, transmission power, Computer Networks and Communications, Hardware and Architecture, Control and Systems Engineering, Signal Processing, Electrical and Electronic Engineering

Abstract

Mobile Ad hoc Networks (MANETs) are intended to work without a fixed framework and provide dependable interchanges to ground vehicles, boats, airplanes, or people and structure a self-mending process that will empower persistent correspondences in any event, when at least one of its nodes are debilitated or briefly expelled from the system. Notwithstanding, MANETs demonstrate themselves to be progressively harder to create for enormous systems with hundreds or thousands more nodes than initially envisioned. In our proposed technique, the node switches its communication mode depending on the connectivity of the adjacent nodes. The transmission power of each node will be calculated with the help of two major scenarios i.e., tree scenario and zone scenario. The autonomous clustering of the nodes among the tree and the zone scenario will be channelized by a comparison of the transmission power (residual energy) among the nodes. The inter and the intra communication of the node is also discussed in the paper. The result will be carried out by the simulation work in various perspectives, such as checking the percentage level of malicious nodes, traffic density, transmission power, and the longevity of nodes.

Published

2022