Abstract
We present a modelling framework for the spreading of epidemics on temporal networks from which both the individual-based and pair-based models can be recovered. The proposed temporal pair-based model that is systematically derived from this framework offers an improvement over existing pair-based models by moving away from edge-centric descriptions while keeping the description concise and relatively simple. For the contagion process, we consider the susceptible–infected–recovered (SIR) model, which is realized on a network with time-varying edges. We show that the shift in perspective from individual-based to pair-based quantities enables exact modelling of Markovian epidemic processes on temporal tree networks. On arbitrary networks, the proposed pair-based model provides a substantial increase in accuracy at a low computational and conceptual cost compared to the individual-based model. From the pair-based model, we analytically find the condition necessary for an epidemic to occur, otherwise known as the epidemic threshold. Due to the fact that the SIR model has only one stable fixed point, which is the global non-infected state, we identify an epidemic by looking at the initial stability of the model.
Highlights
In recent years epidemiological modelling, along with many other fields, has seen renewed activity thanks to the emergence of network science (Newman 2018; Barabasi 2016; Zhan et al 2020; Masuda and Holme 2017)
Results we compare the accuracy of the temporal individual-based (TIB) model and the Temporal Pair-Based (TPB) model against the ground truth MC average, that is, direct stochastic simulations
We run the TIB model and the TPB model for some given parameters β and μ and compare it to the ground truth, which is the average of a number of MC realisations
Summary
In recent years epidemiological modelling, along with many other fields, has seen renewed activity thanks to the emergence of network science (Newman 2018; Barabasi 2016; Zhan et al 2020; Masuda and Holme 2017). Upon substituting the transition rates Iin+1|Sin and Rin+1|Iin under the assumption of statistical independence, the full TIB model is written as
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