Using network motifs to characterize temporal network evolution leading to diffusion inhibition

Sarkar, Soumajyoti; Guo, Ruocheng; Shakarian, Paulo

doi:10.1007/s13278-019-0556-z

Cited by 22 publications

(13 citation statements)

References 55 publications

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“…Several works investigate the role of different topological features in misinformation spread [2,30,35,8], finding that some topic/audience interdependencies may increase the spread of misinformation, perhaps related to cultural norms, experiences or values [7]. Likewise, chains or groups of nodes may accelerate the spread of misinformation [22] and, as Xian et al demonstrate, individuals can be exposed to and share misinformation across platforms [34]. In the context of the current crisis, Cinelli et al [6] analysed spread patterns of different Covid-19 related misinformation across several platforms.…”

Section: Misinformation Spread Analysismentioning

confidence: 99%

Co-spread of Misinformation and Fact-Checking Content During the Covid-19 Pandemic

Burel

Farrell

Mensio

et al. 2020

Lecture Notes in Computer Science

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Section: Misinformation Spread Analysismentioning

confidence: 99%

Co-spread of Misinformation and Fact-Checking Content During the Covid-19 Pandemic

Burel

Farrell

Mensio

et al. 2020

Lecture Notes in Computer Science

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“…Moreover, we intend to extend our analysis to include the estimation of network summaries that are based on the local topology and geometry of the graph. In particular, we intend to incorporate a motif-based analysis (Milo et al, 2002; Dey et al, 2019; Sarkar et al, 2019) and the concepts of topological data analysis (TDA), particularly, persistent homology, in the derivation of graph summary statistics (Carlsson, 2009; Patania et al, 2017; Carlsson, 2019). Indeed, tracking local network topological summaries based on graph persistent homology offers multi-fold benefits.…”

Section: Resultsmentioning

confidence: 99%

Nonparametric Anomaly Detection on Time Series of Graphs

Ofori-Boateng

Gel

Cribben

2019

Preprint

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Identifying change points and/or anomalies in dynamic network structures has become increasingly popular across various domains, from neuroscience to telecommunication to finance. One of the particular objectives of the anomaly detection task from the neuroscience perspective is the reconstruction of the dynamic manner of brain region interactions. However, most statistical methods for detecting anomalies have the following unrealistic limitation for brain studies and beyond: that is, network snapshots at different time points are assumed to be independent. To circumvent this limitation, we propose a distribution-free framework for anomaly detection in dynamic networks. First, we present each network snapshot of the data as a linear object and find its respective univariate characterization via local and global network topological summaries. Second, we adopt a change point detection method for (weakly) dependent time series based on efficient scores, and enhance the finite sample properties of change point method by approximating the asymptotic distribution of the test statistic using the sieve bootstrap. We apply our method to simulated and to real data, particularly, two functional magnetic resonance imaging (fMRI) datasets and the Enron communication graph. We find that our new method delivers impressively accurate and realistic results in terms of identifying locations of true change points compared to the results reported by competing approaches. The new method promises to offer a deeper insight into the large-scale characterizations and functional dynamics of the brain and, more generally, into intrinsic structure of complex dynamic networks.

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“…Second, in this work, we focus on static network structure. But the real-world networks can evolve over time [21,26]. Hence, we would like to investigate how to exploit dynamics in evolving networks for learning ITEs.…”

Section: Discussionmentioning

confidence: 99%

Learning Individual Causal Effects from Networked Observational Data

Guo

Liu

2020

Proceedings of the 13th International Conference on Web Search and Data Mining

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The convenient access to observational data enables us to learn causal effects without randomized experiments. This research direction draws increasing attention in research areas such as economics, healthcare, and education. For example, we can study how a medicine (the treatment) causally affects the health condition (the outcome) of a patient using existing electronic health records. To validate causal effects learned from observational data, we have to control confounding bias -the influence of variables which causally influence both the treatment and the outcome. Existing work along this line overwhelmingly relies on the unconfoundedness assumption that there do not exist unobserved confounders. However, this assumption is untestable and can even be untenable. In fact, an important fact ignored by the majority of previous work is that observational data can come with network information that can be utilized to infer hidden confounders. For example, in an observational study of the individual-level treatment effect of a medicine, instead of randomized experiments, the medicine is often assigned to each individual based on a series of factors. Some of the factors (e.g., socioeconomic status) can be challenging to measure and therefore become hidden confounders. Fortunately, the socioeconomic status of an individual can be reflected by whom she is connected in social networks. With this fact in mind, we aim to exploit the network information to recognize patterns of hidden confounders which would further allow us to learn valid individual causal effects from observational data. In this work, we propose a novel causal inference framework, the network deconfounder, which learns representations to unravel patterns of hidden confounders from the network information. Empirically, we perform extensive experiments to validate the effectiveness of the network deconfounder on various datasets. CCS CONCEPTS• Mathematics of computing → Causal networks; • Networks → Online social networks; • Human-centered computing → Social network analysis.

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Using network motifs to characterize temporal network evolution leading to diffusion inhibition

Cited by 22 publications

References 55 publications

Co-spread of Misinformation and Fact-Checking Content During the Covid-19 Pandemic

Co-spread of Misinformation and Fact-Checking Content During the Covid-19 Pandemic

Nonparametric Anomaly Detection on Time Series of Graphs

Learning Individual Causal Effects from Networked Observational Data

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