Maximizing Social Influence in Nearly Optimal Time
Diffusion is a fundamental graph process, underpinning such phenomena as epidemic disease contagion and the spread of innovation by word-of-mouth. We address the algorithmic problem of finding a set of k initial seed nodes in a network so that the expected size of the resulting cascade is maximized,...
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Main Authors | , , , |
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Format | Journal Article |
Language | English |
Published |
04.12.2012
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Subjects | |
Online Access | Get full text |
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Summary: | Diffusion is a fundamental graph process, underpinning such phenomena as
epidemic disease contagion and the spread of innovation by word-of-mouth. We
address the algorithmic problem of finding a set of k initial seed nodes in a
network so that the expected size of the resulting cascade is maximized, under
the standard independent cascade model of network diffusion. Runtime is a
primary consideration for this problem due to the massive size of the relevant
input networks.
We provide a fast algorithm for the influence maximization problem, obtaining
the near-optimal approximation factor of (1 - 1/e - epsilon), for any epsilon >
0, in time O((m+n)k log(n) / epsilon^2). Our algorithm is runtime-optimal (up
to a logarithmic factor) and substantially improves upon the previously
best-known algorithms which run in time Omega(mnk POLY(1/epsilon)).
Furthermore, our algorithm can be modified to allow early termination: if it is
terminated after O(beta(m+n)k log(n)) steps for some beta < 1 (which can depend
on n), then it returns a solution with approximation factor O(beta). Finally,
we show that this runtime is optimal (up to logarithmic factors) for any beta
and fixed seed size k. |
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DOI: | 10.48550/arxiv.1212.0884 |