TY - JOUR
T1 - A Hybrid Membership Latent Distance Model For Unsigned And Signed Integer Weighted Networks
AU - Nakis, Nikolaos
AU - Çelikkanat, Abdulkadir
AU - Mørup, Morten
N1 - Publisher Copyright:
© World Scientific Publishing Company.
PY - 2023/5/1
Y1 - 2023/5/1
N2 - Graph representation learning (GRL) has become a prominent tool for furthering the understanding of complex networks providing tools for network embedding, link prediction, and node classification. In this paper, we propose the Hybrid Membership-Latent Distance Model (HM-LDM) by exploring how a Latent Distance Model (LDM) can be constrained to a latent simplex. By controlling the edge lengths of the corners of the simplex, the volume of the latent space can be systematically controlled. Thereby communities are revealed as the space becomes more constrained, with hard memberships being recovered as the simplex volume goes to zero. We further explore a recent likelihood formulation for signed networks utilizing the Skellam distribution to account for signed weighted networks and extend the HM-LDM to the signed Hybrid Membership-Latent Distance Model (SHM-LDM). Importantly, the induced likelihood function explicitly attracts nodes with positive links and deters nodes having negative interactions. We demonstrate the utility of HM-LDM and SHM-LDM on several real networks. We find that the procedures successfully identify prominent distinct structures, as well as how nodes relate to the extracted aspects providing favorable performances in terms of link prediction when compared to prominent baselines. Furthermore, the learned soft memberships enable easily interpretable network visualizations highlighting distinct patterns.
AB - Graph representation learning (GRL) has become a prominent tool for furthering the understanding of complex networks providing tools for network embedding, link prediction, and node classification. In this paper, we propose the Hybrid Membership-Latent Distance Model (HM-LDM) by exploring how a Latent Distance Model (LDM) can be constrained to a latent simplex. By controlling the edge lengths of the corners of the simplex, the volume of the latent space can be systematically controlled. Thereby communities are revealed as the space becomes more constrained, with hard memberships being recovered as the simplex volume goes to zero. We further explore a recent likelihood formulation for signed networks utilizing the Skellam distribution to account for signed weighted networks and extend the HM-LDM to the signed Hybrid Membership-Latent Distance Model (SHM-LDM). Importantly, the induced likelihood function explicitly attracts nodes with positive links and deters nodes having negative interactions. We demonstrate the utility of HM-LDM and SHM-LDM on several real networks. We find that the procedures successfully identify prominent distinct structures, as well as how nodes relate to the extracted aspects providing favorable performances in terms of link prediction when compared to prominent baselines. Furthermore, the learned soft memberships enable easily interpretable network visualizations highlighting distinct patterns.
KW - community detection
KW - graph representation learning
KW - latent space modeling
KW - non-negative matrix factorization
KW - Signed networks
UR - http://www.scopus.com/inward/record.url?scp=85173259686&partnerID=8YFLogxK
U2 - 10.1142/S0219525923400027
DO - 10.1142/S0219525923400027
M3 - Journal article
AN - SCOPUS:85173259686
SN - 0219-5259
VL - 26
JO - Advances in Complex Systems
JF - Advances in Complex Systems
IS - 3
M1 - 2340002
ER -