Maximum Weight Independent Sets and Matchings in Sparse Random Graphs. Exact Results using the Local Weak Convergence Method

Abstract

Let G(n,c/n) and Gr(n) be an n-node sparse random graph and a sparse random r-regular graph, respectively, and let I(n,r) and I(n,c) be the sizes of the largest independent set in G(n,c/n) and Gr(n). The asymptotic value of I(n,c)/n as n∞, can be computed using the Karp-Sipser algorithm when c≤ e. For random cubic graphs, r=3, it is only known that .432≤n I(n,3)/n ≤ n I(n,3)≤ .4591 with high probability (w.h.p.) as n∞, as shown by Frieze and Suen and by Bollobas, respectively. In this paper we assume in addition that the nodes of the graph are equipped with non-negative weights, independently generated according to some common distribution, and we consider instead the maximum weight of an independent set. Surprisingly, we discover that for certain weight distributions, the limit n I(n,c)/n can be computed exactly even when c>e, and n I(n,r)/n can be computed exactly for some r≥ 2. For example, when the weights are exponentially distributed with parameter 1, n I(n,2e)/n≈ .5517, and n I(n,3)/n≈ .6077. Our results are established using the recently developed local weak convergence method further reduced to a certain local optimality property exhibited by the models we consider.

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