1 research outputs found
Inferring Degrees from Incomplete Networks and Nonlinear Dynamics
Inferring topological characteristics of complex networks from observed data
is critical to understand the dynamical behavior of networked systems, ranging
from the Internet and the World Wide Web to biological networks and social
networks. Prior studies usually focus on the structure-based estimation to
infer network sizes, degree distributions, average degrees, and more. Little
effort attempted to estimate the specific degree of each vertex from a sampled
induced graph, which prevents us from measuring the lethality of nodes in
protein networks and influencers in social networks. The current approaches
dramatically fail for a tiny sampled induced graph and require a specific
sampling method and a large sample size. These approaches neglect information
of the vertex state, representing the dynamical behavior of the networked
system, such as the biomass of species or expression of a gene, which is useful
for degree estimation. We fill this gap by developing a framework to infer
individual vertex degrees using both information of the sampled topology and
vertex state. We combine the mean-field theory with combinatorial optimization
to learn vertex degrees. Experimental results on real networks with a variety
of dynamics demonstrate that our framework can produce reliable degree
estimates and dramatically improve existing link prediction methods by
replacing the sampled degrees with our estimated degrees.Comment: IJCAI 2020, 7 pages, 4 figures, network inference, incomplete networ