Publication Type:

Journal Article


Ganesan, A.


Wireless Networks, Kluwer Academic Publishers, Volume 20, Number 6, p.1321-1334 (2014)



Access control, Algorithms, Centralized algorithms, Communication overheads, Complex networks, Conflict graph, Fractional chromatic number, Link scheduling, Parallel algorithms, Processing complexity, Quality of service, Scheduling, Vertex coloring problems, Wave interference, Wireless networks, Worst-case performance


Given a wireless network where some pairs of communication links interfere with each other, we study sufficient conditions for determining whether a given set of minimum bandwidth quality-of-service requirements can be satisfied. We are especially interested in algorithms which have low communication overhead and low processing complexity. The interference in the network is modeled using a conflict graph whose vertices correspond to the communication links in the network. Two links are adjacent in this graph if and only if they interfere with each other due to being in the same vicinity and hence cannot be simultaneously active. The problem of scheduling the transmission of the various links is then essentially a fractional, weighted vertex coloring problem, for which upper bounds on the fractional chromatic number are sought using only localized information. We recall some distributed algorithms for this problem, and then assess their worst-case performance. Our results on this fundamental problem imply that for some well known classes of networks and interference models, the performance of these distributed algorithms is within a bounded factor away from that of an optimal, centralized algorithm. The performance bounds are simple expressions in terms of graph invariants. It is seen that the induced star number of a network plays an important role in the design and performance of such networks. © 2013 Springer Science+Business Media New York.


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Cite this Research Publication

A. Ganesan, “Performance of sufficient conditions for distributed quality-of-service support in wireless networks”, Wireless Networks, vol. 20, pp. 1321-1334, 2014.