Pseudo-likelihood-based M-estimation of random graphs with dependent edges and parameter vectors of increasing dimension
An important question in statistical network analysis is how to estimate models of dependent network data without sacrificing computational scalability and statistical guarantees. We demonstrate that scalable estimation of random graph models with dependent edges is possible, by establishing the first consistency results and convergence rates for pseudo-likelihood-based M-estimators for parameter vectors of increasing dimension based on a single observation of dependent random variables. The main results cover models of dependent random variables satisfying weak dependence conditions, and may be of independent interest. To showcase consistency results and convergence rates, we introduce a novel class of generalized β-models with dependent edges and parameter vectors of increasing dimension. We establish consistency results and convergence rates for pseudo-likelihood-based M-estimators of generalized β-models with dependent edges, in dense- and sparse-graph settings.
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