Final size and convergence rate for an epidemic in heterogeneous populations
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Publication:5164227
DOI10.1142/S0218202521500251zbMath1473.92034arXiv2010.15410MaRDI QIDQ5164227
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Publication date: 10 November 2021
Published in: Mathematical Models and Methods in Applied Sciences (Search for Journal in Brave)
Full work available at URL: https://arxiv.org/abs/2010.15410
SIR modelnext generation operatorepidemic spreadstructured population equationslong term asymptotics
Epidemiology (92D30) PDEs in connection with biology, chemistry and other natural sciences (35Q92) Systems of nonlinear integral equations (45G15) Eigenvalue problems for integral equations (45C05) Integro-partial differential equations (35R09)
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Cites Work
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- Generality of the final size formula for an epidemic of a newly invading infectious disease
- The final size of an epidemic and its relation to the basic reproduction number
- The size of epidemics in populations with heterogeneous susceptibility
- On selection dynamics for competitive interactions
- A note on the derivation of epidemic final sizes
- On the definition and the computation of the basic reproduction ratio \(R_ 0\) in models for infectious diseases in heterogeneous populations
- On the spread of epidemics in a closed heterogeneous population
- On selection dynamics for continuous structured populations
- Age-of-infection and the final size relation
- Distributed susceptibility: a challenge to persistence theory in infectious disease models
- A model for the spatial spread of an epidemic
- A final size relation for epidemic models
- Schrödinger operators with singular potentials
- Final Size of an Epidemic for a Two-Group SIR Model
- MODELLING EPIDEMICS AND VIRUS MUTATIONS BY METHODS OF THE MATHEMATICAL KINETIC THEORY FOR ACTIVE PARTICLES
- Heterogeneous social interactions and the COVID-19 lockdown outcome in a multi-group SEIR model
- A mathematical model reveals the influence of population heterogeneity on herd immunity to SARS-CoV-2
- A multiscale model of virus pandemic: Heterogeneous interactive entities in a globally connected world
