research-article

Intelligent core network for Tactile Internet system

Authors:

Abdelhamied A. Ateya,

Ammar Muthanna,

Anastasia Vybornova,

Andrey KoucheryavyAuthors Info & Claims

ICFNDS '17: Proceedings of the International Conference on Future Networks and Distributed Systems

Article No.: 22, Pages 1 - 6

https://doi.org/10.1145/3102304.3102326

Published: 19 July 2017 Publication History

Abstract

Tactile Internet requires a round trip latency of 1ms, which considered being the main challenge with the system realization. Forced by recent development and capabilities of the fifth generation (5G) cellular system, the Tactile Internet will become a real. One way to overcome the 1ms latency is to employ a centralized controller in the core of the network with a global knowledge of the system together with, the concept of network function virtualization (NFV). This is the idea behind the software defined networking (SDN). This paper introduces a Tactile Internet system structure which employs SDN in the core of the cellular network and mobile edge computing (MEC) in multi-levels. The system is simulated over a reliable environment and introduces a round trip latency of orders of 1 ms. This can be interpreted by the reduction of intermediate nodes involved in the communication process.

References

[1]

Simsek, M., Aijaz, A., Dohler, M., Sachs, J. and Fettweis, G., 2016. 5G-enabled tactile internet. IEEE Journal on Selected Areas in Communications, 34(3), pp.460--473.

Digital Library

[2]

Ateya, A.A., Vybornova, A., Kirichek, R. and Koucheryavy, A., 2017, February. Multilevel cloud based Tactile Internet system. In Advanced Communication Technology (ICACT), 2017 19th International Conferenceon (pp. 105--110). IEEE.

[3]

Alliance, N.G.M.N., 2015. 5G white paper. Next generation mobile networks, white paper.

[4]

Liu, Y. and Liu, G., 2017. User-Centric Wireless Network for 5G. In 5G Mobile Communications (pp. 457--473). Springer International Publishing.

[5]

Han, B., Gopalakrishnan, V., Ji, L. and Lee, S., 2015. Network function virtualization: Challenges and opportunities for innovations. IEEE Communications Magazine, 53(2), pp.90--97.

Digital Library

[6]

Karl, H., Dräxler, S., Peuster, M., Galis, A., Bredel, M., Ramos, A., Martrat, J., Siddiqui, M.S., van Rossem, S., Tavernier, W. and Xilouris, G., 2016. DevOps for network functionvirtualisation: an architectural approach. Transactions on Emerging Telecommunications Technologies, 27(9), pp.1206--1215.

Digital Library

[7]

Blanco, B., Fajardo, J.O., Giannoulakis, I., Kafetzakis, E., Peng, S., Pérez-Romero, J., Trajkovska, I., Khodashenas, P.S., Goratti, L., Paolino, M. and Sfakianakis, E., 2017. Technology pillars in the architecture of future 5G mobile networks: NFV, MEC and SDN. Computer Standards & Interfaces.

Digital Library

[8]

Kirichek, R., Vladyko, A., Paramonov, A. and Koucheryavy, A., 2017, February. Software-defined architecture for flying ubiquitous sensor networking. In Advanced Communication Technology (ICACT), 2017 19th International Conferenceon (pp. 158--162). IEEE.

[9]

Athmiya, N.S., Shobha, K.R. and Sarimela, V., 2016, May. Feasibility study and implementation of openflow based SDN controller for tactical scenario. In Recent Trends in Electronics, Information & Communication Technology (RTEICT), IEEE International Conference on (pp. 789--794). IEEE.

[10]

Muthanna, A., Masek, P., Hosek, J., Fujdiak, R., Hussein, O., Paramonov, A. and Koucheryavy, A., 2016, September. Analytical Evaluation of D2D Connectivity Potential in 5G Wireless Systems. In International Conference on Next Generation Wired/Wireless Networking (pp. 395--403). Springer International Publishing.

[11]

Shariat, M., Gutierrez-Estevez, D.M., Vijay, A., Safjan, K., Rugeland, P., Silva, I., Lorca, J., Widmer, J., Fresia, M., Li, Y. and Siaud, I., 2016. 5G radio access above 6 GHz. Transactions on Emerging Telecommunications Technologies, 27(9), pp.1160--1167.

Digital Library

[12]

Jiang, M., Condoluci, M. and Mahmoodi, T., 2016, May. Network slicing management & prioritization in 5G mobile systems. In European Wireless 2016; 22th European Wireless Conference; Proceedings of (pp. 1--6). VDE.

[13]

An, X., Zhou, C., Trivisonno, R., Guerzoni, R., Kaloxylos, A., Soldani, D. and Hecker, A., 2016. On end to end network slicing for 5G communication systems. Transactions on Emerging Telecommunications Technologies.

[14]

Satyanarayanan, M., 2017. The Emergence of Edge Computing. Computer, 50(1), pp.30--39.

Digital Library

[15]

Jin, X., Li, L.E., Vanbever, L. and Rexford, J., 2013, December. Softcell: Scalable and flexible cellular core network architecture. In Proceedings of the ninth ACM conference on Emerging networking experiments and technologies (pp. 163--174). ACM.

Digital Library

[16]

Iovanna, P. and Ubaldi, F., 2015, September. SDN solutions for 5G transport networks. In Photonics in Switching (PS), 2015 International Conference on (pp. 297--299). IEEE.

[17]

Szabo, D., Gulyas, A., Fitzek, F.H. and Lucani, D.E., 2015, May. Towards the tactile internet: decreasing communication latency with network coding and software defined networking. In European Wireless 2015; 21th European Wireless Conference; Proceedings of (pp. 1--6). VDE.

[18]

Chochlidakis, G. and Friderikos, V., 2016, May. Low latency virtual network embedding for mobile networks. In Communications (ICC), 2016 IEEE International Conference on (pp. 1--6). IEEE.

[19]

Wang, K., Wang, Y., Zeng, D. and Guo, S., 2017. An SDN-Based Architecture for Next-Generation Wireless Networks. IEEE Wireless Communications, 24(1), pp.25--31.

Digital Library

[20]

Chih-Lin, I., Han, S., Xu, Z., Sun, Q. and Pan, Z., 2016. 5G: rethink mobile communications for 2020+. Phil. Trans. R. Soc. A, 374(2062), p.20140432.

[21]

"Open vSwitch." {Online}. Available: http://openvswitch.org

[22]

"Open Networking Foundation (ONF)." {Online}. Available: https://www.opennetworking.org/ {Accessed: Feb. 2017}.

[23]

Basta, A., Kellerer, W., Hoffmann, M., Hoffmann, K. and Schmidt, E.D., 2013, November. A virtual SDN-enabled LTE EPC architecture: A case study for S-/P-gateways functions. In Future Networks and Services (SDN4FNS), 2013 IEEE SDN for (pp. 1--7). IEEE.

[24]

Kumar, R. and Sahoo, G., 2014. Cloud computing simulation using CloudSim. arXiv preprint arXiv:1403.3253.

[25]

Son, J., Dastjerdi, A.V., Calheiros, R.N., Ji, X., Yoon, Y. and Buyya, R., 2015, May. Cloudsimsdn: Modeling and simulation of software-defined cloud data centers. In Cluster, Cloud and Grid Computing (CCGrid), 2015 15th IEEE/ACM International Symposium on (pp. 475--484). IEEE.

[26]

Zheng, K., Zhao, L., Mei, J., Dohler, M., Xiang, W. and Peng, Y., 2015. 10 Gb/s hetsnets with millimeter-wave communications: access and networking-challenges and protocols. IEEE Communications Magazine, 53(1), pp.222--231.

Digital Library

[27]

Vladyko, A., Muthanna, A., Kirichek, R.: Comprehensive SDN Testing Based on Model Network. In: Galinina, O., Balandin, S., Koucheryavy, Y. (eds.) Internet of Things, Smart Spaces, and Next Generation. LNCS, vol. 9870, pp. 539--549. Springer International Publishing (2016)

[28]

AAbuarqoub, MH Hammoudeh. Behaviour Profiling in Healthcare Applications Using the Internet of Things Technology - Proceedings of Fourth International Conference on Advances in Information Processing and Communication Technology, 2016

Cited By

R RS HNagarajan SDevarajan GOmar MBashir A(2024)Threat Detection and Mitigation for Tactile Internet Driven Consumer IoT-Healthcare SystemIEEE Transactions on Consumer Electronics10.1109/TCE.2024.337019370:1(4249-4257)Online publication date: Feb-2024
https://doi.org/10.1109/TCE.2024.3370193
Awais MUllah Khan FZafar MMudassar MZaigham Zaheer MMehmood Cheema KKamran MJung W(2023)Towards Enabling Haptic Communications over 6G: Issues and ChallengesElectronics10.3390/electronics1213295512:13(2955)Online publication date: 5-Jul-2023
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Vladimirov SVorozheykina OMuthanna A(2023)8-bit forward error correction codes in linear network codingProceedings of the 7th International Conference on Future Networks and Distributed Systems10.1145/3644713.3644833(712-719)Online publication date: 21-Dec-2023
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Index Terms

Intelligent core network for Tactile Internet system
1. Networks
  1. Network components
    1. Wireless access points, base stations and infrastructure

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cover image ACM Other conferences

ICFNDS '17: Proceedings of the International Conference on Future Networks and Distributed Systems

July 2017

325 pages

ISBN:9781450348447

DOI:10.1145/3102304

Copyright © 2017 ACM.

© 2017 Association for Computing Machinery. ACM acknowledges that this contribution was authored or co-authored by an employee, contractor or affiliate of a national government. As such, the Government retains a nonexclusive, royalty-free right to publish or reproduce this article, or to allow others to do so, for Government purposes only.

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Publication History

Published: 19 July 2017

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ICFNDS '17

ICFNDS '17: International Conference on Future Networks and Distributed Systems

July 19 - 20, 2017

Cambridge, United Kingdom

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Cited By

R RS HNagarajan SDevarajan GOmar MBashir A(2024)Threat Detection and Mitigation for Tactile Internet Driven Consumer IoT-Healthcare SystemIEEE Transactions on Consumer Electronics10.1109/TCE.2024.337019370:1(4249-4257)Online publication date: Feb-2024
https://doi.org/10.1109/TCE.2024.3370193
Awais MUllah Khan FZafar MMudassar MZaigham Zaheer MMehmood Cheema KKamran MJung W(2023)Towards Enabling Haptic Communications over 6G: Issues and ChallengesElectronics10.3390/electronics1213295512:13(2955)Online publication date: 5-Jul-2023
https://doi.org/10.3390/electronics12132955
Vladimirov SVorozheykina OMuthanna A(2023)8-bit forward error correction codes in linear network codingProceedings of the 7th International Conference on Future Networks and Distributed Systems10.1145/3644713.3644833(712-719)Online publication date: 21-Dec-2023
https://dl.acm.org/doi/10.1145/3644713.3644833
Gorbacheva LZakharov MKoucheryavy A(2023)Network algorithm for controlling robotic manipulator system: Prototype ImplementationProceedings of the 7th International Conference on Future Networks and Distributed Systems10.1145/3644713.3644831(694-702)Online publication date: 21-Dec-2023
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Zhetov AKaijalainen VMogilatov VVolkov AMuthanna A(2023)Load Balancing Algorithm in SDN Multicontroller NetworkProceedings of the 7th International Conference on Future Networks and Distributed Systems10.1145/3644713.3644830(689-693)Online publication date: 21-Dec-2023
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Vladimirov SVybornova AMuthanna AKoucheryavy AEl-Latif A(2023)Network Coding Datagram Protocol for TCP/IP NetworksIEEE Access10.1109/ACCESS.2023.326628911(43485-43498)Online publication date: 2023
https://doi.org/10.1109/ACCESS.2023.3266289
Vladimirov S(2023)Pseudo-Random Error-Correcting Codes in Network CodingSecure Edge and Fog Computing Enabled AI for IoT and Smart Cities10.1007/978-3-031-51097-7_4(39-54)Online publication date: 14-Dec-2023
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Yaroshevych RTkachov VKovalenko ARosinskyi D(2022)Modelling the Domain Architecture of the Tactile Internet Using a Foggy Infrastructure2022 IEEE 9th International Conference on Problems of Infocommunications, Science and Technology (PIC S&T)10.1109/PICST57299.2022.10238653(512-516)Online publication date: 10-Oct-2022
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Mahdi MAhmad AQassim QNatiq HSubhi MMahmoud M(2021)From 5G to 6G Technology: Meets Energy, Internet-of-Things and Machine Learning: A SurveyApplied Sciences10.3390/app1117811711:17(8117)Online publication date: 31-Aug-2021
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Marques REpiphaniou GAl-Khateeb HMaple CHammoudeh MDe Castro PDehghantanha AChoo K(2021)A Flow-based Multi-agent Data Exfiltration Detection Architecture for Ultra-low Latency NetworksACM Transactions on Internet Technology10.1145/341910321:4(1-30)Online publication date: 16-Jul-2021
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