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Using approximate majorization to characterize protocol fairness
Proceedings of the 2001 ACM SIGMETRICS international conference on Measurement and modeling of computer systems
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Journal of Computer and System Sciences - Special issue on Internet algorithms
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Market Equilibrium via a Primal-Dual-Type Algorithm
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Approximate majorization and fair online load balancing
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Pricing for fairness: distributed resource allocation for multiple objectives
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FOCS '06 Proceedings of the 47th Annual IEEE Symposium on Foundations of Computer Science
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FOCS '06 Proceedings of the 47th Annual IEEE Symposium on Foundations of Computer Science
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WINE'05 Proceedings of the First international conference on Internet and Network Economics
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Bandwidth allocation in networks: a single dual update subroutine for multiple objectives
CAAN'04 Proceedings of the First international conference on Combinatorial and Algorithmic Aspects of Networking
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GPC '09 Proceedings of the 4th International Conference on Advances in Grid and Pervasive Computing
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We analyze several distributed, continuous time protocols for a fair allocation of bandwidths to flows in a network (or resources to agents). Our protocols converge to an allocation which is a logarithmic approximation, simultaneously, to all canonical social welfare functions (i.e. functions which are symmetric, concave, and non-decreasing). These protocols can be started in an arbitrary state. While a similar protocol was known before, it only applied to the simple bandwidth allocation problem, and its stability and convergence time was not understood. In contrast, our protocols also apply to the more general case of Leontief utilities, where each user may place a different requirement on each resource. Further, we prove that our protocols converge in polynomial time. The best convergence time we prove is O(n log ncmaxamax/cminamin), where n is the number of agents in the network, cmax and cmin are the maximum and minimum capacity of the links, and amax, amin are the largest and smallest Leontief coefficients, respectively. This time is achieved by a simple MIMD (multiplicative increase, multiplicative decrease) protocol which had not been studied before in this setting. We also identify combinatorial properties of these protocols that may be useful in proving stronger convergence bounds. The final allocations by our protocols are supported by usage-sensitive dual prices which are fair in the sense that they shield light users of a resource from the impact of heavy users. Thus our protocols can also be thought of as efficient distributed schemes for computing fair prices.