Approximation of the Diagonal of a Laplacian's Pseudoinverse for Complex Network Analysis
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by
Eugenio Angriman, Maria Predari, Alexander van der Grinten, Henning Meyerhenke
2020
Abstract
The ubiquity of massive graph data sets in numerous applications requires
fast algorithms for extracting knowledge from these data. We are motivated here
by three electrical measures for the analysis of large small-world graphs G =
(V, E)– i.e., graphs with diameter in O(log |V|), which are abundant in
complex network analysis. From a computational point of view, the three
measures have in common that their crucial component is the diagonal of the
graph Laplacian's pseudoinverse, L^†. Computing diag(L^†)
exactly by pseudoinversion, however, is as expensive as dense matrix
multiplication – and the standard tools in practice even require cubic time.
Moreover, the pseudoinverse requires quadratic space – hardly feasible for
large graphs. Resorting to approximation by, e.g., using the
Johnson-Lindenstrauss transform, requires the solution of O(log |V| /
ϵ^2) Laplacian linear systems to guarantee a relative error, which is
still very expensive for large inputs.
In this paper, we present a novel approximation algorithm that requires the
solution of only one Laplacian linear system. The remaining parts are purely
combinatorial – mainly sampling uniform spanning trees, which we relate to
diag(L^†) via effective resistances. For small-world networks, our
algorithm obtains a ±ϵ-approximation with high probability, in a
time that is nearly-linear in |E| and quadratic in 1 / ϵ. Another
positive aspect of our algorithm is its parallel nature due to independent
sampling. We thus provide two parallel implementations of our algorithm: one
using OpenMP, one MPI + OpenMP. In our experiments against the state of the
art, our algorithm (i) yields more accurate results, (ii) is much faster and
more memory-efficient, and (iii) obtains good parallel speedups, in particular
in the distributed setting.
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