On the formulation of epidemic models (an appraisal of Kermack and McKendrick)

Approximation of eigenvalues of evolution operators for linear coupled renewal and retarded functional differential equations, A non-standard numerical scheme for an age-of-infection epidemic model, A phenomenological estimate of the true scale of CoViD-19 from primary data, A structured population model with diffusion in structure space, INTEGRAL MODEL OF COVID-19 SPREAD AND MITIGATION IN UK: IDENTIFICATION OF TRANSMISSION RATE, Solvability in weighted \(L_1\)-spaces for the \(m\)-product of integral equations and model of the dynamics of the capillary rise, Mathematical analysis for an age-structured SIRS epidemic model, Equivalence of the Erlang-Distributed SEIR Epidemic Model and the Renewal Equation, Coupled and uncoupled dynamic mode decomposition in multi-compartmental systems with applications to epidemiological and additive manufacturing problems, A systematic procedure for incorporating separable static heterogeneity into compartmental epidemic models, Immuno-epidemiology of a population structured by immune status: a mathematical study of waning immunity and immune system boosting, Real-time growth rate for general stochastic SIR epidemics on unclustered networks, Necessary and sufficient stability conditions for integral delay systems, Identification of time delays in COVID-19 data, Solvability of the product of \(n\)-integral equations in Orlicz spaces, Generality of endemic prevalence formulae, Piecewise orthogonal collocation for computing periodic solutions of renewal equations, Epidemic dynamics and adaptive vaccination strategy: renewal equation approach, Coupled Systems of Renewal Equations for Forces of Infection through a Contact Network, Numerical continuation and delay equations: a novel approach for complex models of structured populations, A geometric analysis of the SIR, SIRS and SIRWS epidemiological models, Dynamical impacts of the coupling in a model of interactive infectious diseases, Collocation Techniques for Structured Populations Modeled by Delay Equations, A didactical note on the advantage of using two parameters in Hopf bifurcation studies, Game dynamic model of optimal budget allocation under individual vaccination choice, Global stability properties of a class of renewal epidemic models, A self-organizing criticality mathematical model for contamination and epidemic spreading, Approximation of Eigenvalues of Evolution Operators for Linear Renewal Equations, Equivalent probability density moments determine equivalent epidemics in an SIRS model with temporary immunity, Analysis of an epidemiological model structured by time-since-last-infection, Floquet theory and stability of periodic solutions of renewal equations, A model of an epidemic mapping, Epidemic dynamics and host immune response: a nested approach, Threshold phenomenon and traveling waves for heterogeneous integral equations and epidemic models, A time-Since-infection model for populations with two pathogens, Modeling nonlocal behavior in epidemics via a reaction-diffusion system incorporating population movement along a network, Rumour propagation: an operational research approach by computational and information theory, Equations with infinite delay: numerical bifurcation analysis via pseudospectral discretization, Modelling and optimising healthcare interventions in a model with explicit within- and between-host dynamics, Back to the roots: a discrete Kermack-McKendrick model adapted to Covid-19

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• The final size of an epidemic and its relation to the basic reproduction number
• Analysis of a vaccine model with cross-immunity: when can two competing infectious strains coexist?
• Equations with infinite delay: blending the abstract and the concrete
• The model of Kermack and McKendrick for the plague epidemic in Bombay and the type reproduction number with seasonality
• Analysis of an SEIRS epidemic model with two delays
• Epidemiological models with age structure, proportionate mixing, and cross-immunity
• Integral equation models for endemic infectious diseases
• Prelude to Hopf bifurcation in an epidemic model: Analysis of a characteristic equation associated with a nonlinear Volterra integral equation
• Introduction to functional differential equations
• The dynamics of cocirculating influenza strains conferring partial cross-immunity
• Bifurcation theory. An introduction with applications of PDEs
• An evolutionary epidemiological mechanism, with applications to type A influenza
• An endemic model with variable re-infection rate and applications to influenza
• Delay equations. Functional-, complex-, and nonlinear analysis
• An SIS epidemic model with variable population size and a delay
• An SEIR epidemic model with constant latency time and infectious period
• Global stability for epidemic model with constant latency and infectious periods
• Dynamics of influenza A drift: The linear three-strain model
• Stability and bifurcations in an epidemic model with varying immunity period
• Subthreshold coexistence of strains: the impact of vaccination and mutation
• Strain replacement in an epidemic model with super-infection and perfect vaccination
• An Epidemic Model With Post-Contact Prophylaxis of Distributed Length II. Stability and Oscillations if Treatment is Fully Effective
• A Two-Strain Tuberculosis Model with Age of Infection
• Stability and Bifurcation Analysis of Volterra Functional Equations in the Light of Suns and Stars
• An epidemic model with post-contact prophylaxis of distributed length I. Thresholds for disease persistence and extinction
• Lyapunov functional and global asymptotic stability for an infection-age model
• On a nonlinear integral equation modelling an epidemic in an age-structured population.
• Nonlinear Oscillations in Epidemic Models
• Limiting behaviour in an epidemic model
• How May Infection-Age-Dependent Infectivity Affect the Dynamics of HIV/AIDS?
• Endemic Models with Arbitrarily Distributed Periods of Infection I: Fundamental Properties of the Model
• Contributions to the mathematical theory of epidemics. III.—Further studies of the problem of endemicity
• Sustained oscillations in an evolutionary epidemiological model of influenza A drift
• Kermack and McKendrick revisited: The variable subsceptibility model for infectious deseases