Dynamics of COVID-19 models with asymptomatic infections and quarantine measures

Abstract

Considering the propagation characteristics of COVID-19 in different regions, the dynamics analysis and numerical demonstration of long-term and short-term models of COVID-19 are carried out, respectively. The long-term model is devoted to investigate the global stability of COVID-19 model with asymptomatic infections and quarantine measures. By using the limit system of the model and Lyapunov function method, it is shown that the COVID-19-free equilibrium V0 is globally asymptotically stable if the control reproduction number Rc<1 and globally attractive if Rc=1, which means that COVID-19 will die out; the COVID-19 equilibrium V is globally asymptotically stable if Rc>1, which means that COVID-19 will be persistent. In particular, to obtain the local stability of V, we use proof by contradiction and the properties of complex modulus with some novel details, and we prove the weak persistence of the system to obtain the global attractivity of V. Moreover, the final size of the corresponding short-term model is calculated and the stability of its multiple equilibria is analyzed. Numerical simulations of COVID-19 cases show that quarantine measures and asymptomatic infections have a non-negligible impact on the transmission of COVID-19.