Reciprocity, community detection, and link prediction in dynamic networks

Hypergraphs, encoding structured interactions among any number of system units, have recently proven a successful tool to describe many real-world biological and social networks. Here we propose a framework based on statistical inference to characterize the structural organization of hypergraphs. The method allows to infer missing hyperedges of any size in a principled way, and to jointly detect overlapping communities in presence of higher-order interactions. Furthermore, our model has an efficient numerical implementation, and it runs faster than dyadic algorithms on pairwise records projected from higher-order data. We apply our method to a variety of real-world systems, showing strong performance in hyperedge prediction tasks, detecting communities well aligned with the information carried by interactions, and robustness against addition of noisy hyperedges. Our approach illustrates the fundamental advantages of a hypergraph probabilistic model when modeling relational systems with higher-order interactions.

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“…Such a condition could in principle be relaxed following the approaches of refs. 53 – 55 , we do not explore this here.…”

Section: Resultsmentioning

confidence: 99%

Inference of hyperedges and overlapping communities in hypergraphs

2022

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“…As accurately identifying anomalies is deeply connected with the chosen null model determining what regular patterns are, it is important to consider other possible mechanism for tie formation, beyond community structure. In recent works [31][32][33], we found that modeling community patterns together with reciprocity effects, leads to higher predictive performance, thus more expressive generative models. This could significantly change the performance of our foundational model as well.…”

Section: Discussionmentioning

confidence: 86%

Anomaly detection and community detection in networks

Safdari¹,

Bacco²

2022

Preprint

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Anomaly detection is a relevant problem in the area of data analysis. In networked systems, where individual entities interact in pairs, anomalies are observed when pattern of interactions deviates from patterns considered regular. Properly defining what regular patterns entail relies on developing expressive models for describing the observed interactions. It is crucial to address anomaly detection in networks. Among the many well-known models for networks, latent variable models -a class of probabilistic models -offer promising tools to capture the intrinsic features of the data. In this work, we propose a probabilistic generative approach which incorporates domain knowledge, i.e., community membership, as a fundamental model for regular behavior, and thus flag potential anomalies deviating from this pattern. In fact, community membership act as the building blocks of a null model to identify the regular interaction patterns. The structural information is included in the model through latent variables for community membership and anomaly parameter. The algorithm aims at inferring these latent parameters and then output the labels identifying anomalies on the network edges.

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“…Yasami Y et al [15] noted information that related to the dynamic features of node interactions, analyzed the properties of multilayer networks, and modeled the evolution of network topologies at different layers by an infinite factorial hidden Markov model of feature cascades. Safdari et al [16] noted the importance of additional parameters that captured structural properties. Therefore, they presented a probabilistic generative model that integrated these parameters and network communities as structural information.…”

Section: B Probability Models-based Link Predictionmentioning

confidence: 99%

Link Prediction Model for Opportunistic Networks Based on Feature Fusion

2022

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Link prediction is a hot issue in the research of network evolution. The existing methods employ a stacked structure, which feeds captured topology information into a time series model. However, the structure introduces network noise that affects the accurate extraction of temporal features and reduces the prediction accuracy. Motivated by feature fusion methods in the Computer Vision(CV), we introduce a link prediction model based on attentional feature fusion (AFF-LP), which automatically extracts network features through the Deep Learning. The proposed model leverages the self-attention mechanism to extract the topological and temporal features respectively. Moreover, the network features are fused based on a graph-level representation. With the help of a vector mapping model, the feature vectors are mapped to the future network topology. Three real opportunistic network datasets, ITC, MIT and Infocom06, are used for experiments. The experimental results show that the proposed model is more accurate and stable compared to other baseline methods.

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Reciprocity, community detection, and link prediction in dynamic networks

Cited by 28 publications

References 31 publications

Inference of hyperedges and overlapping communities in hypergraphs

Inference of hyperedges and overlapping communities in hypergraphs

Anomaly detection and community detection in networks

Link Prediction Model for Opportunistic Networks Based on Feature Fusion

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