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Photonic Network Communications
Erschienen in: Photonic Network Communications 1/2021

15.06.2021 | Original Paper

A fault-tolerant topology control algorithm for wireless ultraviolet light covert communication network in cluster UAV

verfasst von: Zhao Taifei, Song Shiyuan

Erschienen in: Photonic Network Communications | Ausgabe 1/2021

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Abstract

In the wireless ultraviolet sensor network, interference causes data retransmission, which is not conducive to communication between sensor nodes. Aiming at the serious communication interference problem of three-dimensional k-connected wireless ultraviolet light sensor network, this paper proposes a novel low-interference wireless ultraviolet network fault-tolerant topology control algorithm. The number of vertices disjoint paths between nodes and base stations is used as a fault-tolerance index to reduce network interference and ensure two-way fault tolerance between nodes and base stations. At the same time, genetic algorithm crossover and mutation operators are used to construct a particle swarm optimization algorithm, which is used to solve a reasonable power distribution scheme from the fault-tolerant network constructed by the 3D k-YG algorithm. The performance of the proposed algorithm is verified through simulation experiments. The experimental results show that the proposed algorithm can not only construct fault-tolerant topology, but also effectively reduce network interference.
Vorheriger Artikel Reliability improvement of satellite-based quantum key distribution systems using retransmission scheme
Nächster Artikel A spectrum spacing mechanism to enhance traffic grooming in elastic optical networks

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Literatur
1.
Alexander, V., HarilaosG, S., Dimitris, V.: Connectivity issues for ultraviolet UV-C networks[J]. J Opt Communications 3(3), 199–205 (2011)CrossRef
2.
Chen, G., Abou-Galala, F., Xu, Z., Sadler, B.M.: Experimental evaluation of LED-based solar blind NLOS communication links. Opt Expr 16(19), 15059–15068 (2008)CrossRef
3.
Jieun, Yu., Heejun, R., Lee Wonjun, Du., Ding-Zhu. : Topology control in cooperative wireless ad-hoc networks J]. IEEE J Sel Areas Communications. 30(9), 1771–1779 (2012)CrossRef
4.
Zhao, T., Gao, Y., Wu, P., et al.: A networking strategy for three-dimensional wireless ultraviolet communication network[J]. Optik 151, 123–135 (2017)CrossRef
5.
Zhang Xue, Lu., Sanglu, C.G., et al.: Topology control for wireless sensor networks [J]. Journal of Software 18(4), 943–954 (2007)CrossRef
6.
Bahramgiri, M., Hajiaghayi, M., Mirrokni, V.S.: Fault-tolerant and3-di-mensional distributed topology control algorithms in wireless multi-hop networks [J]. Wireless Netw. 12(2), 179–188 (2006)CrossRef
7.
Wang, Y., Cao, L.J., Dahlberg, T.A., et al.: Self-organizing fault-tolerant topology control in large-scale three-dimensional wireless networks[J]. ACM Transactions on Autonomous and Adaptive Systems 4(3), 1923 (2009)CrossRef
8.
Lu-qiao, Z., Qing-xin, Z., Tao, Lv., et al.: Interference-aware topology optimization in wireless sensor network[J]. Journal of University of Electronic Science and Technology of China 40(4), 564–567 (2011)
9.
Wang, D., Long, W., Li, X.H.: An interference-reducing topology control for 3D wireless sensor networks [J]. J. Comput. Theor. Nanosci. 10(2), 442–450 (2013)CrossRef
10.
Pahl, P.J., Damrath, R.: Mathematical foundations of computational engineering a handbook [M], pp. 559–568. Springer, New York, USA (2001)CrossRef
11.
Zhao, T., Li, Q., Song, P.: A fast channel assignment scheme based on power control in wireless ultraviolet networks[J]. Computers & Electrical Engineering 56, 262 (2016)CrossRef
12.
Wang, D., Long, W., Li, X.H.: An interference-reducing topology control for 3D wireless sensor networks[J]. Journal of Computational and Theoretical Nanoscience 10(2), 442–450 (2013)CrossRef
13.
Zhang, S., Huang, Q., Hongshou, W.U., et al:. A modified particle swarm optimizer for optimal operation of hydropower station[J]. Journal of Hydroelectric Engineering 26(1), 1–5 (2007)
14.
Bagci, H., Korpeoglu, I., Yazici, A.: A Distributed Fault-Tolerant Topology Control Algorithm for Heterogeneous Wireless Sensor Networks[J]. IEEE Trans Parallel Distrib Syst 26(4), 914–923 (2015)CrossRef
15.
Hong, Z., Wang, R., Li, X.: A clustering-tree topology control based on the energy forecast for heterogeneous wireless sensor networks. Journal of Automatica Sinica 3, 68–77 (2016)MathSciNetCrossRef
16.
Huang, M., Chen, S., Zhu, Y., et al.: Topology control for time-evolving and predictable delay-tolerant networks. IEEE Trans. Comput. 62, 2308–2321 (2013)MathSciNetCrossRef
17.
Chen, H., Shi, K.: Topology control for predictable delay-tolerant networks based on probability. Ad Hoc Netw. 24, 147–159 (2015)CrossRef
18.
Chen, H., Shi, K., Wu, C.: Spanning tree based topology control for data collecting in predictable delay-tolerant networks. Ad Hoc Netw. 46, 48–60 (2016)CrossRef
19.
Chen, H., Shi, K., Lin, Y.: Data collection oriented topology control for predictable delay-tolerant networks. Ubiquitous Intelligence and Computing, Bali 9–12, 325–330 (2014)
20.
Chen, B., Jamieson, K., Balakrishnan, H., et al.: Span: an energy-efficient coordination algorithm for topology maintenance in ad hoc wireless networks. Wireless Netw. 8, 481–494 (2002)CrossRef
21.
Hongbo, W., Yaoxue, Z., Xiaohui, W., et al.: A Suitable Size Clustering Algorithm for Ad Hoc Wireless Networks[J]. J. Softw. 13(9), 1741–1756 (2002)
22.
Mathew, R., Younis, M., Elsharkawy, S.M.: Energy-efficient bootstrapping for wireless sensor networks[J]. Innov. Syst. Softw. Eng. 1(2), 205–220 (2005)CrossRef
23.
Gui, J., Hui, L., Xiong, N.: A game-based localized multi-objective topology control scheme in heterogeneous wireless networks. IEEE Access 5, 2396–2416 (2017)CrossRef
24.
Xenakis, A., Fouklas, F., Stamoulis, G., Katsavounidis, I.: Topology control with coverage and lifetimeoptimization of wireless sensor networks with unequal energy distribution. Comput. Electr. Eng. 64, 182–199 (2017)CrossRef
Metadaten
Titel
A fault-tolerant topology control algorithm for wireless ultraviolet light covert communication network in cluster UAV
verfasst von
Zhao Taifei
Song Shiyuan
Publikationsdatum
15.06.2021
Verlag
Springer US
Erschienen in
Photonic Network Communications / Ausgabe 1/2021
Print ISSN: 1387-974X
Elektronische ISSN: 1572-8188
DOI
https://doi.org/10.1007/s11107-021-00936-w

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