Affiliation:
1. Tongji University
2. University of Western Australia
3. CSIRO
4. University of Shanghai for Science and Technology
Abstract
Continuous-state network spreading models provide critical numerical and analytic insights into transmission processes in epidemiology, rumor propagation, knowledge dissemination, and many other areas. Most of these models reflect only local features such as adjacency, degree, and transitivity, so can exhibit substantial error in the presence of global correlations typical of empirical networks. Here, we propose mitigating this limitation via a network property ideally suited to capturing spreading. This is the network correlation dimension, which characterizes how the number of nodes within range of a source typically scales with distance. Applying the approach to susceptible-infected-recovered processes leads to a spreading model which, for a wide range of networks and epidemic parameters, can provide more accurate predictions of the early stages of a spreading process than important established models of substantially higher complexity. In addition, the proposed model leads to a basic reproduction number that provides information about the final state not available from popular established models.
Published by the American Physical Society
2024
Funder
National Natural Science Foundation of China
Australian Research Council
Science and Technology Commission of Shanghai Municipality
Natural Science Foundation of Shanghai
Fundamental Research Funds for the Central Universities
Publisher
American Physical Society (APS)
Cited by
1 articles.
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