Understanding Signed Diverse Multiplex Networks: Clustering and Inference

Keeping signs of edges in network construction improves accuracy for clustering and estimation.

The paper introduces the Signed Generalized Random Dot Product Graph (SGRDPG) model, extending it to a multiplex version. It emphasizes the importance of maintaining edge signs for better precision in estimation and clustering. The study explores various stochastic network models, focusing on relationships between nodes across layers. By employing novel algorithms, the paper ensures consistent clustering of layers and high subspace estimation accuracy. The research demonstrates theoretical guarantees through numerical simulations and real data examples, showcasing the benefits of signed networks in analysis. The content delves into balancing theory in signed networks and its implications on clusterability. Various authors' perspectives on balance theory are discussed, highlighting contrasting conclusions drawn from real-world network studies.

L ≤ nτ0 where τ0 is a constant. P(|A(i,j)| = 1) = |P(i,j)|, sign(A(i,j)) = sign(P(i,j)). bΣ(m) = (n - 1)^(-1/2) eD(m)(eO(m))^T. max |Θ(l1,l2)| ≤ CK n^(-1) log(n). E[(A(l))^2(i,i)] ≠ [(P(l))^2(i,i)] due to diagonal elements bias.

"We propose the Signed Generalized Random Dot Product Graph (SGRDPG) model which generates an edge between nodes with probability |Pi,j|." "The allure of the strong balance formulation lies in the fact that strongly balanced networks are clusterable." "Keeping signs in the process of construction leads to better accuracy of statistical inference." "Our paper makes several key contributions including introducing a very flexible signed SGRDPG network model." "Our simulations establish that keeping edge signs improves accuracy of estimation and clustering."