Abstract

Traditional fact checking by expert journalists cannot keep up with the enormous volume of information that is now generated online. Computational fact checking may significantly enhance our ability to evaluate the veracity of dubious information. Here we show that the complexities of human fact checking can be approximated quite well by finding the shortest path between concept nodes under properly defined semantic proximity metrics on knowledge graphs. Framed as a network problem this approach is feasible with efficient computational techniques. We evaluate this approach by examining tens of thousands of claims related to history, entertainment, geography, and biographical information using a public knowledge graph extracted from Wikipedia. Statements independently known to be true consistently receive higher support via our method than do false ones. These findings represent a significant step toward scalable computational fact-checking methods that may one day mitigate the spread of harmful misinformation.

Keywords

MisinformationComputer scienceScalabilityTheoretical computer scienceKnowledge graphModel checkingPath (computing)Data scienceArtificial intelligenceComputer security

MeSH Terms

AlgorithmsArea Under CurveHumansKnowledgeROC Curve

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Publication Info

Year
2015
Type
article
Volume
10
Issue
6
Pages
e0128193-e0128193
Citations
493
Access
Closed

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Cite This

Giovanni Luca Ciampaglia, Prashant Shiralkar, Luís M. Rocha et al. (2015). Computational Fact Checking from Knowledge Networks. PLoS ONE , 10 (6) , e0128193-e0128193. https://doi.org/10.1371/journal.pone.0128193

Identifiers

DOI
10.1371/journal.pone.0128193
PMID
26083336
PMCID
PMC4471100

Data Quality

Data completeness: 86%