%0 Journal Article %1 IJACSA.2014.050116 %A N&\#233;meth, G&\#225;bor %D 2014 %J International Journal of Advanced Computer Science and Applications(IJACSA) %K L\^{}p competitive conges\&\#172;tion; coordinates feasible hyper--spherical l\^{}p norm; oblivious of polytope; probability ratio; region; routing; throughput %N 1 %T On A New Competitive Measure For Oblivious Routing %U http://ijacsa.thesai.org/ %V 5 %X Oblivious routing algorithms use only locally avail&\#172;able information at network nodes to forward traffic, and as such, a plausible choice for distributed implementations. It is a natural desire to quantify the performance penalty we pay for this distributedness. Recently, R&\#228;cke has shown that for general undirected graphs the competitive ratio is only O(log n), that is, the maximum congestion caused by the oblivious algorithm is within a logarithmic factor of the best possible congestion. And while the performance penalty is larger for directed networks (Azar gives a O(vn) lower bound), experiments on many real-world topologies show that it usually remains under 2. These competitive measures, however, are of worst-case type, and therefore do not always give adequate characterization. The more different combinations of demands a routing algorithm can accommodate in the network without congestion, the better. Driven by this observation, in this paper we introduce a new competitive measure, the volumetric competitive ratio, as the measure of all admissible demands compared to the measure of demands routed without congestion. The main result of the paper is a general lower bound on the volumetric ratio; and we also show a directed graph with O(1) competitive ratio that exhibits O(n) volumetric ratio. Our numerical evaluations show that the competitivity of oblivious routing in terms of the new measure quickly vanishes even in relatively small common-place topologies.

@article{IJACSA.2014.050116, abstract = {Oblivious routing algorithms use only locally avail\&\#172;able information at network nodes to forward traffic, and as such, a plausible choice for distributed implementations. It is a natural desire to quantify the performance penalty we pay for this distributedness. Recently, R\&\#228;cke has shown that for general undirected graphs the competitive ratio is only O(log n), that is, the maximum congestion caused by the oblivious algorithm is within a logarithmic factor of the best possible congestion. And while the performance penalty is larger for directed networks (Azar gives a O(vn) lower bound), experiments on many real-world topologies show that it usually remains under 2. These competitive measures, however, are of worst-case type, and therefore do not always give adequate characterization. The more different combinations of demands a routing algorithm can accommodate in the network without congestion, the better. Driven by this observation, in this paper we introduce a new competitive measure, the volumetric competitive ratio, as the measure of all admissible demands compared to the measure of demands routed without congestion. The main result of the paper is a general lower bound on the volumetric ratio; and we also show a directed graph with O(1) competitive ratio that exhibits O(n) volumetric ratio. Our numerical evaluations show that the competitivity of oblivious routing in terms of the new measure quickly vanishes even in relatively small common-place topologies. }, added-at = {2014-02-21T08:00:08.000+0100}, author = {N\&\#233;meth, G\&\#225;bor}, biburl = {https://www.bibsonomy.org/bibtex/2287c7bad8501ae28d29007bd5df86ef7/thesaiorg}, interhash = {85ef860e1c2af72894ce53d9d8374c9c}, intrahash = {287c7bad8501ae28d29007bd5df86ef7}, journal = {International Journal of Advanced Computer Science and Applications(IJACSA)}, keywords = {L\^{}p competitive conges\&\#172;tion; coordinates feasible hyper--spherical l\^{}p norm; oblivious of polytope; probability ratio; region; routing; throughput}, number = 1, timestamp = {2014-02-21T08:00:08.000+0100}, title = {{On A New Competitive Measure For Oblivious Routing}}, url = {http://ijacsa.thesai.org/}, volume = 5, year = 2014 }