Surges of Collective Human Activity Emerge from Simple Pairwise Correlations

Human populations exhibit complex behaviors—characterized by long-range correlations and surges in activity—across a range of social, political, and technological contexts. Yet it remains unclear where these collective behaviors come from or if there even exists a set of unifying principles. Indeed,...

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Main Authors: Christopher W. Lynn, Lia Papadopoulos, Daniel D. Lee, Danielle S. Bassett
Format: Article
Language:English
Published: American Physical Society 2019-02-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.9.011022
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spelling doaj-66b78c172ac743239521e251e3049b252020-11-25T00:07:57ZengAmerican Physical SocietyPhysical Review X2160-33082019-02-019101102210.1103/PhysRevX.9.011022Surges of Collective Human Activity Emerge from Simple Pairwise CorrelationsChristopher W. LynnLia PapadopoulosDaniel D. LeeDanielle S. BassettHuman populations exhibit complex behaviors—characterized by long-range correlations and surges in activity—across a range of social, political, and technological contexts. Yet it remains unclear where these collective behaviors come from or if there even exists a set of unifying principles. Indeed, existing explanations typically rely on context-specific mechanisms, such as traffic jams driven by work schedules or spikes in online traffic induced by significant events. However, analogies with statistical mechanics suggest a more general mechanism: that collective patterns can emerge organically from fine-scale interactions within a population. Here, across four different modes of human activity, we show that the simplest correlations in a population—those between pairs of individuals—can yield accurate quantitative predictions for the large-scale behavior of the entire population. To quantify the minimal consequences of pairwise correlations, we employ the principle of maximum entropy, making our description equivalent to an Ising model whose interactions and external fields are notably calculated from past observations of population activity. In addition to providing accurate quantitative predictions, we show that the topology of learned Ising interactions resembles the network of interhuman communication within a population. Together, these results demonstrate that fine-scale correlations can be used to predict large-scale social behaviors, a perspective that has critical implications for modeling and resource allocation in human populations.http://doi.org/10.1103/PhysRevX.9.011022
collection DOAJ
language English
format Article
sources DOAJ
author Christopher W. Lynn
Lia Papadopoulos
Daniel D. Lee
Danielle S. Bassett
spellingShingle Christopher W. Lynn
Lia Papadopoulos
Daniel D. Lee
Danielle S. Bassett
Surges of Collective Human Activity Emerge from Simple Pairwise Correlations
Physical Review X
author_facet Christopher W. Lynn
Lia Papadopoulos
Daniel D. Lee
Danielle S. Bassett
author_sort Christopher W. Lynn
title Surges of Collective Human Activity Emerge from Simple Pairwise Correlations
title_short Surges of Collective Human Activity Emerge from Simple Pairwise Correlations
title_full Surges of Collective Human Activity Emerge from Simple Pairwise Correlations
title_fullStr Surges of Collective Human Activity Emerge from Simple Pairwise Correlations
title_full_unstemmed Surges of Collective Human Activity Emerge from Simple Pairwise Correlations
title_sort surges of collective human activity emerge from simple pairwise correlations
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2019-02-01
description Human populations exhibit complex behaviors—characterized by long-range correlations and surges in activity—across a range of social, political, and technological contexts. Yet it remains unclear where these collective behaviors come from or if there even exists a set of unifying principles. Indeed, existing explanations typically rely on context-specific mechanisms, such as traffic jams driven by work schedules or spikes in online traffic induced by significant events. However, analogies with statistical mechanics suggest a more general mechanism: that collective patterns can emerge organically from fine-scale interactions within a population. Here, across four different modes of human activity, we show that the simplest correlations in a population—those between pairs of individuals—can yield accurate quantitative predictions for the large-scale behavior of the entire population. To quantify the minimal consequences of pairwise correlations, we employ the principle of maximum entropy, making our description equivalent to an Ising model whose interactions and external fields are notably calculated from past observations of population activity. In addition to providing accurate quantitative predictions, we show that the topology of learned Ising interactions resembles the network of interhuman communication within a population. Together, these results demonstrate that fine-scale correlations can be used to predict large-scale social behaviors, a perspective that has critical implications for modeling and resource allocation in human populations.
url http://doi.org/10.1103/PhysRevX.9.011022
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