Abstract
Software-defined wide-area network (SD-WAN) is gaining strong momentum as distributed cloud evolves. The new cloud infrastructure requires novel and innovative network technologies based on virtualization, automated resource (e.g., datacenters, VMs, networks) convergence, ultra-high data-forwarding performance, and strict network security. To meet the demands, this paper suggests a scheme for logically isolated group network for virtual convergence environment and evaluates its performance in terms of virtual network generation performance over the de facto SD-WAN infrastructure deployed on the advanced research network (KREONET), which operates in six distant cities in Korea and the USA.
Similar content being viewed by others
References
What is Software Defined WAN (or SD-WAN)? https://www.sdxcentral.com/sdn/definitions/software-defined-sdn-wan/
Coady Y et al (2015) Distributed cloud computing: applications, status quo, and challenges. ACM SIGCOMM Comput Commun Rev 45(2):38–43
Jain R et al (2013) Network virtualization and software defined networking for cloud computing: a survey. IEEE Commun Mag 51(11):24–31
Garcia Lopez P et al (2015) Edge-centric computing: vision and challenges. ACM SIGCOMM Comput Commun Rev 45(5):37–42
Keegan N et al (2016) A survey of cloud-based network intrusion detection analysis. Hum Cent Comput Inf Sci 6(1):19
Mininet Network Emulator. http://mininet.org/
Official KREONET Website. http://www.kreonet.net
KREONET-S project website. http://www.kreonet-s.net
Kim D et al (2016) Software-defined wide area network adopting virtual dedicate networks. Adv Sci Lett 22(9):2262–2267
KREONET-S implements An SD-WAN connection from South Korea to the StarLight international/national communications exchange facility In Chicago: inaugurating novel advanced international communications services. http://www.startap.net/starlight/PUBLICATIONS/KREONET-S.html
Internet2 web site. http://www.internet2.edu/
Developing Applications with Networking Capabilities via End-to-End SDN web site. https://www.dances-sdn.org/
Open Network Operating System (ONOS) web site. http://onosproject.org/
ESNet web site. https://www.es.net/
AmLight web site. https://www.amlight.net/
Ibarra JG et al (2016) AmLight backbone transition to SDN: celebrating the second anniversary. GLIF Lambda grid workshop 2016, Miami, 26 Sep 2016
GEANT web site (2017). http://www.geant.org/
Mendiola A et al (2017) Towards an SDN-based bandwidth on demand service for the European research community. In: 2017 International Conference on Networked Systems (NetSys), IEEE
COREEN Cloud Service. http://coreen.kreonet.net/
Partnership & Leadership for the nationwide Supercomputing Infrastructure. http://www.plsi.or.kr/
Kim JS et al (2013) HTCaaS: leveraging distributed supercomputing infrastructures for large-scale scientific computing. In: IEEE/ACM 6th Workshop on Many-Task Computing on Clouds, Grids, and Supercomputers (MTAGS’13) Held with SC13
Kim YH et al (2016) A fast algorithm for generating virtual dedicate network based on software-defined wide area network. In: Advances in Computer Science and Ubiquitous Computing. Springer, Singapore, pp 799–805
Tsai JC et al (2013) Cloud-empowered multimedia service: an automatic video storytelling tool. J Converg 4(3):13–19
Salam MI et al (2015) Implementation of searchable symmetric encryption for privacy-preserving keyword search on cloud storage. Hum Cent Comput Inf Sci 5:19
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Kim, D., Kim, YH., Kim, KH. et al. Logically isolated group network for virtual convergence environment over SD-WAN. J Supercomput 74, 6742–6752 (2018). https://doi.org/10.1007/s11227-018-2282-0
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11227-018-2282-0