Paper Detail

Simpson's paradox explains the ubiquity of nonlinear, threshold, and complex contagions

Laurent Hébert-Dufresne, Antoine Allard, Jean-Gabriel Young, William H. W. Thompson, Guillaume St-Onge

Browse

Workflow Queues

arxiv Score 5.2

Published 2026-05-01 · First seen 2026-05-04

General AI

Open paper source

Abstract

Complex contagions describe systems where the probability or rate of contagious transmission is a nonlinear function of the exposure to contagious agents. These models were first studied theoretically but have since been used to capture effects such as nonconformism, social reinforcement or peer pressure in empirical data. However, recent studies have shown that local correlations (e.g., group structure or temporal burstiness) and heterogeneity (e.g., diversity of parameters or covariates) can give the illusion of nonlinear effects even when the dynamics is actually linear. We briefly review these studies to inform a new model and explanation for these effective models of complex contagions. We find global threshold dynamics and superlinear complex contagions even in populations where agents are distributed across social groups described solely by linear or even sublinear contagions. This effect can be understood as a manifestation of Simpson's paradox. Incidence data from heterogeneous groups can look superlinear once averaged over all groups, since the sampling of groups represented at high incidence is biased towards those with stronger local transmission. We then define what we call a Simpson's contagion: a contagion process that looks superlinear when observed over an entire population, but is mechanistically linear or even sublinear in all of its subgroups. By exploring these Simpson's contagions over mathematical case studies, our work contributes to the growing body of literature on the ubiquity of threshold and complex contagions as effective models, and our results stress the pitfall of model selection that ignores correlations and heterogeneity in populations.

Workflow Status

Review status
pending
Role
unreviewed
Read priority
later
Vote
Not set.
Saved
no
Collections
Not filed yet.
Next action
Not filled yet.

Reading Brief

No structured notes yet. Add `summary_sections`, `why_relevant`, `claim_impact`, or `next_action` in `papers.jsonl` to enrich this view.

Why It Surfaced

No ranking explanation is available yet.

Tags

No tags.

Similar Papers

Artificial Intelligence and the Structure of Mathematics 2026-04-07 · Score 4.8 General AI Dive into Claude Code: The Design Space of Today's and Future AI Agent Systems 2026-04-14 · Score 5.5 General AI The Agentification of Scientific Research: A Physicist's Perspective 2026-04-16 · Score 11.3 General AI SHOW3D: Capturing Scenes of 3D Hands and Objects in the Wild 2026-03-30 · Score 3.8 General AI Seeing Fast and Slow: Learning the Flow of Time in Videos 2026-04-23 · Score 10.3 General AI

BibTeX

@article{hbertdufresne2026simpson,
  title = {Simpson's paradox explains the ubiquity of nonlinear, threshold, and complex contagions},
  author = {Laurent Hébert-Dufresne and Antoine Allard and Jean-Gabriel Young and William H. W. Thompson and Guillaume St-Onge},
  year = {2026},
  abstract = {Complex contagions describe systems where the probability or rate of contagious transmission is a nonlinear function of the exposure to contagious agents. These models were first studied theoretically but have since been used to capture effects such as nonconformism, social reinforcement or peer pressure in empirical data. However, recent studies have shown that local correlations (e.g., group structure or temporal burstiness) and heterogeneity (e.g., diversity of parameters or covariates) can g},
  url = {https://arxiv.org/abs/2605.00791},
  keywords = {physics.soc-ph},
  eprint = {2605.00791},
  archiveprefix = {arXiv},
}

Metadata

{}