Estimates for solutions in a model of reptile population dynamics

We consider a model of reptile population dynamics in which the gender of the future individuals depends on the environment temperature. The model is described by a system of delay differential equations in which the delay parameter is responsible for the time spent by individuals in immature age. We study the case of complete extinction of the entire population and the case of stabilization of the population size at a constant value. In each case Lyapunov–Krasovskii functionals are constructed, with the help of which we establish estimates characterizing the rate of extinction of the population in the first case and the rate of stabilization of the population size in the second. Using the obtained estimates, it is possible to evaluate the time for which the population size will reach the equilibrium state.

1. Demidenko G. V. and Matveeva I. I., “Asymptotic properties of solutions to delay differential equations [in Russian],” Vestn. Novosib. Gos. Univ., Ser. Mat. Mekh. Inform., 5, No. 3, 20–28 (2005).

2. Demidenko G. V. and Matveeva I. I., “Stability of solutions to delay differential equations with periodic coefficients of linear terms,” Sib. Math. J., 48, No. 5, 824–836 (2007).

3. Matveeva I. I., “Estimates for solutions to one class of nonlinear delay differential equations,” J. Appl. Ind. Math., 7, No. 4, 557–566 (2013).

4. Demidenko G. V.,“Onthe second Lyapunov method for delay equations [in Russian],” preprint No. 289, Sib. Otdel. Ross. Akad. Nauk, Inst. Mat., Novosibirsk (2014).

5. Yskak T., “Estimates for solutions of one class to systems of nonlinear differential equations with distributed delay [in Russian],” Sib. Elektron. Mat. Izv., 17, 2204–2215 (2020).

6. Matveeva I. I., “Estimates for solutions to one class of nonlinear nonautonomous systems with time-varying concentrated and distributed delays,” Sib. Elektron. Mat. Izv., 18, No. 2, 1689–1697 (2021).

7. Demidenko G. V. and Matveeva I. I., “The second Lyapunov method for time-delay systems,” in: Functional Differential Equations and Applications (A. Domoshnitsky, A. Rasin, S. Padhi, eds.), pp. 145–167, Springer Nature, Singapore (2021) (Springer Proc. Math. Stat.; vol. 379).

8. Matveeva I. I., “Estimates for solutions to one class of nonautonomous systems with time varying concentrated and distributed delays [in Russian],” Mat. Zamet. SVFU, 29, No. 3, 70–79 (2022).

9. Skvortsova M. A., “Estimates for solutions in the model of interaction of populations with several delays [in Russian],” Itogi Nauki Tekhn., Ser. Sovrem. Mat. Prilozh., Temat. Obz., 188, 84–105 (2020).

10. Skvortsova M. A. and Yskak T., “Asymptotic behavior of solutions in one predator–prey model with delay,” Sib. Math. J., 62, No. 2, 324–336 (2021).

11. Skvortsova M. A. and Yskak T., “Estimates of solutions to differential equations with distributed delay describing the competition of several types of microorganisms,” J. Appl. Ind. Math., 16, No. 4, 800–808 (2022).

12. Skvortsova M. A., “Estimates for solutions for one model of population dynamics with delay [in Russian],” Mat. Zamet. SVFU, 29, No. 3, 80–92 (2022).

13. Gallegos A., Plummer T., Uminsky D., Vega C., Wickman C., and Zawoiski M., “A mathematical model of a crocodilian population using delay-differential equations,” J. Math. Biol., 57, 737–754 (2008).