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Tight Bounds for the Min-Max Boundary Decomposition Cost of Weighted Graphs
Many load balancing problems that arise in scientific computing applications
ask to partition a graph with weights on the vertices and costs on the edges
into a given number of almost equally-weighted parts such that the maximum
boundary cost over all parts is small.
Here, this partitioning problem is considered for bounded-degree graphs
G=(V,E) with edge costs c: E->R+ that have a p-separator theorem for some p>1,
i.e., any (arbitrarily weighted) subgraph of G can be separated into two parts
of roughly the same weight by removing a vertex set S such that the edges
incident to S in the subgraph have total cost at most proportional to (SUM_e
c^p_e)^(1/p), where the sum is over all edges e in the subgraph.
We show for all positive integers k and weights w that the vertices of G can
be partitioned into k parts such that the weight of each part differs from the
average weight by less than MAX{w_v; v in V}, and the boundary edges of each
part have cost at most proportional to (SUM_e c_e^p/k)^(1/p) + MAX_e c_e. The
partition can be computed in time nearly proportional to the time for computing
a separator S of G.
Our upper bound on the boundary costs is shown to be tight up to a constant
factor for infinitely many instances with a broad range of parameters. Previous
results achieved this bound only if one has c=1, w=1, and one allows parts with
weight exceeding the average by a constant fraction.Comment: 41 pages, full version of a paper that will appear in SPAA`0