research-article

Enabling simulation services for digital twins of 5G/B5G mobile networks

Authors:

Giovanni Nardini,

Giovanni SteaAuthors Info & Claims

Volume 213, Issue C

Pages 33 - 48

https://doi.org/10.1016/j.comcom.2023.10.017

Published: 27 February 2024 Publication History

Abstract

Digital Twins (DTs) have been proposed as digital replicas of physical entities (e.g., manufacturing equipment), which one can observe in real-time and interact with. Digital Twins of Networks (DTNs) are increasingly being discussed in the literature, as an enabler for efficient data-driven network management and performance-driven network optimization (e.g., to support dynamic reconfiguration, or anticipate the effects of faults). A DTN includes service mapping models, i.e. models that can be fed with acquired data to produce insight on the network itself - e.g., to run what-if scenarios, based on multiple underlying technologies, from Machine Learning to analytical models, e.g. Markov Chains. In this paper we examine the case of DTNs of mobile networks, DTMNs, tailored to 5G and beyond, where issues of dynamic reconfiguration and fault anticipation are critical. We argue that simulation services should be offered by the DTMN in order to allow performance-driven network optimization, and that discrete-event network simulators are ideal instruments to be employed for this purpose. We discuss the challenges that need be addressed to make this happen, e.g., centralized vs. distributed implementation, gathering input from the physical network, security issues and hosting, and we review the possibilities offered by network simulation in terms of what-if analysis, defining the concepts of lockstep and branching analysis. We present a framework to endow a DTMN with simulation services and we exemplify it using Simu5G, a popular 5G/B5G simulation library for OMNeT++, as a reference case study.

References

[1]

F. Tao, H. Zhang, A. Liu, A.Y.C. Nee, Digital twin in industry: state-of-the-art, IEEE Trans. Ind. Inf. 15 (4) (2019) 2405–2415.

[2]

W. Kritzinger, M. Karner, G. Traar, J. Henjes, W. Sihn, Digital Twin in manufacturing: a categorical literature review and classification, IFAC-PapersOnLine 51 (11) (2018) 1016–1022,. ISSN 2405-8963.

[3]

R. Minerva, G.M. Lee, N. Crespi, Digital twin in the IoT context: a survey on technical features, scenarios, and architectural models, 10 Proceedings of the IEEE, vol. 108, 2020, pp. 1785–1824,. October.

[4]

H. Ahmadi, A. Nag, Z. Khar, K. Sayrafian, S. Rahardja, Networked twins and twins of networks: an overview on the relationship between digital twins and 6G, 4 in: IEEE Communications Standards Magazine, vol. 5, 2021, pp. 154–160,. December.

[5]

M. Vaezi, et al., Digital twins from a networking perspective, 23 IEEE Internet of Things Journal, vol. 9, 2022, pp. 23525–23544,. 1 Dec.1.

[6]

A. Lombardo, G. Morabito, S. Quattropani, C. Ricci, Design, implementation, and testing of a microservices-based Digital Twins framework for network management and control, in: 2022 IEEE 23rd International Symposium on a World of Wireless, Mobile and Multimedia Networks (WoWMoM), 2022, pp. 590–595,. Belfast, United Kingdom.

[7]

G. Lin, J. Gel, Y. Wu, H. Li, L. Li, Digital twin networks: learning dynamic network behaviors from network flows, in: 2022 IEEE Symposium on Computers and Communications (ISCC), 2022, pp. 1–6,. Rhodes, Greece.

[8]

L. Zhao, G. Han, Z. Li, L. Shu, Intelligent digital twin-based software-defined vehicular networks, IEEE Network, vol. 34, 2020, pp. 178–184,. September/October.

[9]

M. Kherbache, M. Maimour, E. Rondeau, Network digital twin for the industrial Internet of things, in: 2022 IEEE 23rd International Symposium on a World of Wireless, Mobile and Multimedia Networks, WoWMoM), Belfast, United Kingdom, 2022, pp. 573–578,.

[10]

C. Zhou, et al., Digital twin network: concept and reference architecture, in: Internet Draft Draft-Zhou-Nmrg-Digitaltwin-Network-Concepts-07, 2022, 5 March.

[11]

C. Zhou, et al., Data collection requirements and technologies for digital twin network, in: Internet Draft Draft-Zcz-Nmrg-Digitaltwin-Data-Collection-01, 2022, 7 November.

[12]

J. Paillisse, et al., Performance-Oriented Digital Twins for Packet and Optical Networks (v2), in: IETF Network Management Research Group, 2022, https://datatracker.ietf.org/doc/html/draft-paillisse-nmrg-performance-digital-twin-02 24 October.

[13]

H.X. Nguyen, R. Trestian, D. To, M. Tatipamula, Digital twin for 5G and beyond, IEEE Communications Magazine, vol. 59, February 2021, pp. 10–15,. 2.

Digital Library

[14]

A. Mozo, A. Karamchandani, M. Sanz, J.I. Moreno, A. Pastor, B5GEMINI: digital twin network for 5G and beyond, Budapest, Hungary in: NOMS 2022-2022 IEEE/IFIP Network Operations and Management Symposium, 2022, pp. 1–6,. April.

Digital Library

[15]

M. Farreras, P. Soto, M. Camelo, L. Fàbrega, P. Vilà, Predicting network performance using GNNs: generalization to larger unseen networks, Budapest, Hungary in: NOMS 2022-2022 IEEE/IFIP Network Operations and Management Symposium, 2022, pp. 1–6,.

Digital Library

[16]

N.P. Kuruvatti, M.A. Habibi, S. Partani, B. Han, A. Fellan, H.D. Schotten, Empowering 6G communication systems with digital twin technology: a comprehensive survey, IEEE Access, vol. 10, 2022, pp. 112158–112186,.

[17]

ns3 Network Simulator" Website: https://www.nsnam.org, accessed January 2023.

[18]

N. Patriciello, S. Lagen, B. Bojovic, L. Giupponi, An E2E simulator for 5G NR networks, Simulat. Model. Pract. Theor. 96 (2019),.

[19]

OMNeT++ Discrete Event Simulator" Website: https://omnetpp.org, accessed January 2023.

[20]

G. Nardini, D. Sabella, G. Stea, P. Thakkar, A. Virdis, Simu5G – an OMNeT++ library for end-to-end performance evaluation of 5G networks, IEEE Access (2020),.

[21]

G. Nardini, G. Stea, A. Virdis, Scalable real-time emulation of 5G networks with Simu5G, IEEE Access 9 (2021) 148504–148520,.

[22]

Y. Gao, H. Lv, Y. Hou, J. Liu, W. Xu, Real-time modeling and simulation method of digital twin production line, in: 2019 IEEE 8th Joint International Information Technology and Artificial Intelligence Conference (ITAIC), 2019, pp. 1639–1642.

[23]

M. Schluse, J. Rossmann, From simulation to experimentable digital twins: simulation-based development and operation of complex technical systems, in: IEEE International Symposium on Systems Engineering (ISSE), 2016, pp. 1–6.

[24]

U. Dahmen, J. Rossmann, Experimentable digital twins for a modeling and simulation-based engineering approach, in: 2018 IEEE International Systems Engineering Symposium (ISSE), 2018, pp. 1–8.

[25]

M. Barbi, A.A. Ruiz, A.M. Handzel, S. Inca, D. Garcia-Roger, J.F. Monserrat, Simulation-based digital twin for 5G connected automated and autonomous vehicles, in: 2022 Joint European Conference on Networks and Communications & 6G Summit (EuCNC/6G Summit), 2022, pp. 273–278,. Grenoble, France.

[26]

G. Nardini, G. Stea, Using Network Simulators as Digital Twins of 5G/B5G Mobile Networks, TwinNets2022 Belfast, UK, 2022, pp. 14–17. June.

[27]

3GPP TS 23.288 v.17.4.0, 5G; Architecture Enhancements for 5G System (5GS) to Support Network Data Analytics Services (Release 17), 2022, May.

[28]

A. Arnaz, J. Lipman, M. Abolhasan, M. Hiltunen, Toward integrating intelligence and programmability in open radio access networks: a comprehensive survey, IEEE Access, vol. 10, 2022, pp. 67747–67770,.

[29]

B.R. Barricelli, E. Casiraghi, D. Fogli, A survey on digital twin: definitions, characteristics, applications, and design implications, IEEE Access, vol. 7, 2019, pp. 167653–167671.

[30]

S. Kekki, MEC in 5G networks, 2018, June https://www.etsi.org/images/files/ETSIWhitePapers/etsi_wp28_mec_in_5G_FINAL.pdf.

[31]

ETSI GS MEC 013 v2.2.1, "Multi-access Edge Computing (MEC); Location API", January 2022.

[32]

G. Nardini, A. Noferi, P. Ducange, G. Stea, Exploiting Simu5G for generating datasets for training and testing AI models for 5G/6G network applications, Elsevier SoftwareX 21 (2023),. ISSN 2352-7110.

[33]

INET Framework" Website: https://inet.omnetpp.org, accessed January 2023.

[34]

C. Sommer, R. German, F. Dressler, Bidirectionally coupled network and road traffic simulation for improved IVC analysis, 1 IEEE Transactions on Mobile Computing, vol. 10, 2011, pp. 3–15,. Jan.

Digital Library

[35]

A. Noferi, G. Nardini, G. Stea, A. Virdis, Rapid prototyping and performance evaluation of ETSI MEC-based applications, Elsevier Simulat. Model. Pract. Theor. 123 (2023),. February.

[36]

Y.-N.R. Li, M. Chen, J. Xu, L. Tian, K. Huang, Power saving techniques for 5G and beyond, IEEE Access, vol. 8, 2020, pp. 108675–108690,.

[37]

B. Debaillie, C. Desset, F. Louagie, A flexible and future-proof power model for cellular base stations, in: 2015 IEEE 81st Vehicular Technology Conference (VTC Spring), 2015, pp. 1–7.

[38]

E. Peltonen, et al., 6G White Paper on Edge Intelligence, 2020, arXiv:2004.14850, April.

[39]

P. Almasan, et al., Digital Twin Network: Opportunities and Challenges, 2022, arXiv:2201.01144v2 [cs.NI], 7 Jan.

[40]

Y. Wu, K. Zhang, Y. Zhang, Digital twin networks: a survey 18, 18 IEEE Internet of Things Journal 8 (2021) 13789–13804,. 15 Sept.15.

Index Terms

Enabling simulation services for digital twins of 5G/B5G mobile networks

Index terms have been assigned to the content through auto-classification.

Recommendations

Extending NCTUns simulator to support mobile networks
Simutools '09: Proceedings of the 2nd International Conference on Simulation Tools and Techniques

NCTUns is a Linux based network simulator/emulator which has a great deal of features such as the possibility to execute real world applications without modifications, and provision to model a wide range of network devices using real TCP/IP network ...
Generative AI Empowered Network Digital Twins: Architecture, Technologies, and Applications
The rapid advancement of mobile networks highlights the limitations of traditional network planning and optimization methods, particularly in modeling, evaluation, and application. Network Digital Twins, which simulate networks in the digital domain for ...
A Primer for Real-Time Simulation of Large-Scale Networks
ANSS-41 '08: Proceedings of the 41st Annual Simulation Symposium (anss-41 2008)

Real-time network simulation refers to simulating computer networks in real time so that the virtual network can interact with real implementations of network protocols, network services, and distributed applications. In this paper, we present the ...

Comments

Information & Contributors

Information

Published In

cover image Computer Communications

Computer Communications Volume 213, Issue C

Jan 2024

383 pages

Issue’s Table of Contents

The Authors.

Publisher

Elsevier Science Publishers B. V.

Netherlands

Publication History

Published: 27 February 2024

Author Tags

Qualifiers

Research-article

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

0
Total Citations
0
Total Downloads

Downloads (Last 12 months)0
Downloads (Last 6 weeks)0

Reflects downloads up to 17 Jan 2025

Other Metrics

View Author Metrics

Citations

View Options

View options

Media

Figures

Other

Tables

View Issue’s Table of Contents