Title :
On the fitness of geographic graph generators for modelling physical level topologies
Author :
Cetinkaya, Egemen K. ; Alenazi, Mohammed J. F. ; Yufei Cheng ; Peck, A.M. ; Sterbenz, James P. G.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Univ. of Kansas, Lawrence, KS, USA
Abstract :
The Internet topology has been studied extensively for decades. However, the emphasis of Internet topology research has been on logical level topologies. On the other hand, physical level topologies are necessary to study the resilience of networks realistically. In this paper, we analyse the structure of synthetic geographic topologies whose node locations are given by those of actual physical level graphs. Our results indicate that the synthetic Gabriel graphs capture the grid-like structure of physical level networks. Moreover, given that the cost of physical level topologies is an important aspect from a design perspective, we also compare the cost of several synthetically generated geographic graphs and find that the synthetic Gabriel graphs achieve the smallest cost among all of the graph models that we consider.
Keywords :
Internet; graph theory; telecommunication network topology; Internet topology; geographic graph generators; graph model; grid-like structure; logical level topology; node location; physical level graphs; physical level networks; physical level topology modelling; synthetic Gabriel graphs; synthetic geographic topology; Analytical models; Cities and towns; Conferences; Network topology; Sociology; Statistics; Topology; Gabriel; Internet; Waxman graph; backbone; biconnectivity; connectivity; geographical threshold; geometric; location constrained graph; modelling; network cost model; optimisation; physical level graphs; population weighted graph; provider;
Conference_Titel :
Ultra Modern Telecommunications and Control Systems and Workshops (ICUMT), 2013 5th International Congress on
Conference_Location :
Almaty
Print_ISBN :
978-1-4799-1376-3
DOI :
10.1109/ICUMT.2013.6798402
