Parallel randomized load balancing: A lower bound for a more general model

We extend the lower bound of Adler et al. (1998)  [1] and Berenbrink et al. (1999)  [2] for parallel randomized load balancing algorithms. The setting in these asynchronous and distributed algorithms is of n balls and n bins. The algorithms begin by each ball choosing d bins independently and unifor...

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Veröffentlicht in:Theoretical computer science Jg. 412; H. 22; S. 2398 - 2408
Hauptverfasser: Even, Guy, Medina, Moti
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Oxford Elsevier B.V 13.05.2011
Elsevier
Schlagworte:
Algorithmics. Computability. Computer arithmetics
Algorithms
Applied sciences
Balls and bins
Bins
Collisions
Computer science; control theory; systems
Computer simulation
Exact sciences and technology
Load balancing
Lower bounds
Miscellaneous
Proving
Static randomized parallel allocation
Symmetry
Theoretical computing
Topology
Balls and bins
Lower bounds
Load balancing
Static randomized parallel allocation
Lower bound
Parallel algorithm
Asynchronous
Computer theory
Static allocation
Decision
Assignment
Maximum
Distributed algorithm
Proof
Communication
Symmetry
ISSN:0304-3975, 1879-2294
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Zusammenfassung:We extend the lower bound of Adler et al. (1998)  [1] and Berenbrink et al. (1999)  [2] for parallel randomized load balancing algorithms. The setting in these asynchronous and distributed algorithms is of n balls and n bins. The algorithms begin by each ball choosing d bins independently and uniformly at random. The balls and bins communicate to determine the assignment of each ball to a bin. The goal is to minimize the maximum load, i.e., the number of balls that are assigned to the same bin. In Adler et al. (1998) [1] and Berenbrink et al. (1999)   [2], a lower bound of Ω ( log n / log log n r ) is proved if the communication is limited to r rounds. Three assumptions appear in the proofs in Adler et al. (1998) [1] and Berenbrink et al. (1999)  [2]: the topological assumption, random choices of confused balls, and symmetry. The topological assumption states that each ball’s decision is based only on collisions between choices of balls. The confused ball assumption states that if a ball obtains the same topological information from all its chosen bins, then the ball commits to one of the chosen bins by flipping a fair coin. The symmetry assumption states that all the balls run identical algorithms, the same assumption holds for the bins. We extend the proof of the lower bound so that it holds without these three assumptions. This lower bound applies to every parallel randomized load balancing algorithm we are aware of (Adler et al., 1998 [1]; Berenbrink et al., 1999 [2]; Stemann, 1996 [3]; Even and Medina, 2009 [4]).
Bibliographie:ObjectType-Article-2
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ISSN:0304-3975
1879-2294
DOI:10.1016/j.tcs.2011.01.033