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Wireless Personal Communications
Erschienen in: Wireless Personal Communications 4/2021

10.04.2021

Mobility Aware Quality Enhanced Cluster Based Routing Protocol for Mobile Ad-Hoc Networks Using Hybrid Optimization Algorithm

verfasst von: K. Karthick, R. Asokan

Erschienen in: Wireless Personal Communications | Ausgabe 4/2021

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Abstract

Wireless Sensor Networks (WSN) utilizes more nodes to forward messages and information from source node to destination node and these nodes are battery-powered devices. Thus, Energy saving is always vital role of Routing Protocols which need to maximize the lifetime of WSN. Mobile ad hoc networks (MANET) are self-starting and self-constructing multichip wireless networks in which, the assembly of the system deviates vigorously. This is mainly due to the mobility of the nodes. The nodes in the network not only act as hosts but also as routers that route data from other nodes in network. MANETs require an efficient routing protocol that achieves the quality of service (QoS) mechanism. They are not considering the mobility as one constraint for those problems. Because, mobility of nodes causes frequent link failures and high error rates, so it makes difficult to maintain the desired QoS in the network. To overcome those problems, we propose mobility aware routing protocol for MANET using hybrid optimization (MARP-HO) algorithm, which maximizes the QoS in data transmission. The proposed routing protocol comprises of two phases. The clustering process consists of cluster formation and cluster head (CH) selection. First, the energy efficient clustering is done by improved animal migration optimization (IAMO) algorithm. Then, we gather multiple constraints are energy consumption, received signal strength, mobility and cooperative rate from each cluster member. The gathered constraints used to compute the node cost of each cluster member, here the highest cost node act as CH of cluster. Second, we compute routing path between source–destination using improved ant colony optimization (IACO) algorithm. The proposed MARP-HO routing protocol is compared with existing state-of-art routing protocols in terms of energy consumption, delivery ratio, loss ratio, link stability, delay, network lifetime, number of dead nodes and throughput.
Vorheriger Artikel Data Association Coverage Algorithm Based on Energy Balance and Controlled Parameters in Wireless Sensor Networks
Nächster Artikel A Lightweight and Scalable Physical Layer Attack Detection Mechanism for the Internet of Things (IoT) Using Hybrid Security Schema

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Literatur
1.
Shashidhara, D. N., Chandrappa, D. N., & Puttamadappa, C. (2020). A novel location aware content prefetching technique for mobile adhoc network. Procedia Computer Science, 171, 1970–1978.CrossRef
2.
Zemrane, H., Baddi, Y., & Hasbi, A. (2019). Mobile adhoc networks for intelligent transportation system: Comparative analysis of the routing protocols. Procedia Computer Science, 160, 758–765.CrossRef
3.
Manohar, S., Rajasekar, V., & Muthurasu, N., (2020). Energy optimization and reliable message communication in mobile adhoc networks using packet shifting. Materials today: Proceedings.
4.
Alappatt, V., & Prathap, P. J. (2020). Hybrid cryptographic algorithm based key management scheme in MANET. Materials today: Proceedings.
5.
Gautam, D., & Tokekar, V. (2020). A novel approach for detecting DDoS attack in MANET. Materials Today: Proceedings, 29, 674–677.
6.
Karunkuzhali, D., Prasad, M., Singh, G., Kaur, A., Periasamy, J. K., & Ramprabu, G. (2020). Traffic analysis in vehicular adhoc networks using flow and network level analysis. Microprocessors and Microsystems, p. 103450.
7.
Rajendran, N., Jawahar, P. K., & Priyadarshini, R. (2019). Cross centric intrusion detection system for secure routing over black hole attacks in MANETs. Computer Communications, 148, 129–135.CrossRef
8.
Jaron, A., Mihailovic, A., & Aghvami, A. H. (2016). Qos-aware multi-plane routing method for OSPF-based IP access networks. Computer Networks, 99, 1–14.CrossRef
9.
Lv, J., Wang, X., Zhang, Q., & Huang, M. (2018). LAPGN: Accomplishing information consistency under OSPF in General Networks (an extension). Journal of Network and Computer Applications, 119, 57–69.CrossRef
10.
Carrascal Frias, V., Diaz Delgado, G., Zavala Ayala, A., & Aguilar Igartua, M. (2007). MM-DSR: Multipath QoS routing for multiple multimedia sources over ad hoc mobile networks. IEEE Latin America Transactions, 5(6), 448–456.CrossRef
11.
Lippert, S., & Spagnolo, G. (2008). Internet peering as a network of relations. Telecommunications Policy, 32(1), 33–49.CrossRef
12.
Griffin, T., Shepherd, F., & Wilfong, G. (2002). The stable paths problem and interdomain routing. IEEE/ACM Transactions on Networking, 10(2), 232–243.CrossRef
13.
Gao, L., Griffin, T., & Rexford, J. (2001). Inherently safe backup routing with BGP. In Proceedings IEEE INFOCOM. Conference on computer communications. Twentieth annual joint conference of the IEEE Computer and Communications Society (Cat. No.01CH37213).
14.
McGovern, E. (1998). Controlling the environmental impact of transport: Traffic management schemes and their influence on consumer behaviour. Sustainable Development, 6(1), 23–30.CrossRef
15.
Pan, P., Hahne, E., & Schulzrinne, H. (2000). BGRP: Sink-tree-based aggregation for inter-domain reservations. Journal of Communications and Networks, 2(2), 157–167.CrossRef
16.
Kadusic, E., Zivic, N., & Kos, A. (2016). QoS-aware dynamic MAP selection in HMIPv6 architectures. IEEE Access, 4, 3112–3126.CrossRef
17.
Xiao, L., Wang, J., Lui, K., & Nahrstedt, K. (2004). Advertising interdomain QoS routing information. IEEE Journal on Selected Areas in Communications, 22(10), 1949–1964.CrossRef
18.
Nivetha, S., Asokan, R., & Senthilkumaran, N. (2013). A swarm-based hybrid routing protocol to support multiple Quality of Service (QoS) metrics in mobile ad hoc networks. In 2013 fourth international conference on computing, communications and networking technologies (ICCCNT).
19.
Farooq, M., & Butt, A. (2009). Hybrid differentiated service architecture for QoS routing in mobile ad hoc networks. In 2009 IEEE 13th international multitopic conference.
20.
Wu, B., Chi, C., & Xu, S. (2007). Service selection model based on QoS reference vector. In 2007 IEEE congress on services (Services 2007).
21.
Chaudhari, S., & Biradar, R. (2016). Traffic and mobility aware resource prediction using cognitive agent in mobile ad hoc networks. Journal of Network and Computer Applications, 72, 87–103.CrossRef
22.
González, S., Castellanos, W., Guzmán, P., Arce, P., & Guerri, J. (2016). Simulation and experimental testbed for adaptive video streaming in ad hoc networks. Ad Hoc Networks, 52, 89–105.CrossRef
23.
Khoukhi, L., & Cherkaoui, S. (2010). Intelligent QoS management for multimedia services support in wireless mobile ad hoc networks". Computer Networks, 54(10), 1692–1706.CrossRef
24.
Colonnese, S., Cuomo, F., Guida, R., & Melodia, T. (2015). Performance evaluation of sender-assisted HTTP-based video streaming in wireless ad hoc networks. Ad Hoc Networks, 24, 74–84.CrossRef
25.
Kuo, J., Shih, C., Ho, C., & Chen, Y. (2013). A cross-layer approach for real-time multimedia streaming on wireless peer-to-peer ad hoc network. Ad Hoc Networks, 11(1), 339–354.CrossRef
26.
Lal, C., Laxmi, V., Gaur, M., & Conti, M. (2016). Enhancing QoE for video streaming in MANETs via multi-constraint routing. Wireless Networks, 24(1), 235–256.CrossRef
27.
Bao, Y., Lei, W., Zhang, W., & Zhan, Y. (2016). QoE collaborative evaluation method based on fuzzy clustering heuristic algorithm. SpringerPlus, 5(1), 1–29.CrossRef
28.
Umar, M., Alrajeh, N., & Mehmood, A. (2016). SALMA: An efficient state-based hybrid routing protocol for mobile nodes in wireless sensor networks. International Journal of Distributed Sensor Networks, 12(2), 2909618.CrossRef
29.
30.
31.
Asokan, R., & Saravanan, K. (2011). Distributed denial of service (DoS) attacks detection mechanism. International Journal of Computer Science, Engineering and Information Technology (IJCSEIT), 5.
32.
Asokan, R., Natarajan, A. M., & Venkatesh C. (2008). Quality-of-service routing using path and power aware techniques in mobile ad hoc networks. Journal of Computer Systems, Networks, and Communications, 2008, pp 1.
33.
Asokan, R., Natarajan, A. M., & Nivetha, A. (2007). A swarm-based distance vector routing to support multiple quality of service (QoS) metrics in mobile ad hoc networks. Journal of Computer Science, 3(9), 700–707.CrossRef
34.
Asokan, R., Natarajan, A. M., & Venkatesh, C. (2008). Ant bases dynamic source routing protocol to support multiple quality of services (QoS) metrics in mobile adhoc networks. International Journal of Computer Science and Security, 2(3), 48–56.
Metadaten
Titel
Mobility Aware Quality Enhanced Cluster Based Routing Protocol for Mobile Ad-Hoc Networks Using Hybrid Optimization Algorithm
verfasst von
K. Karthick
R. Asokan
Publikationsdatum
10.04.2021
Verlag
Springer US
Erschienen in
Wireless Personal Communications / Ausgabe 4/2021
Print ISSN: 0929-6212
Elektronische ISSN: 1572-834X
DOI
https://doi.org/10.1007/s11277-021-08387-2

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