Bibliography

Jenita Jahangir

Ackleh, A. S., Jahangir, J., and Veprauskas, A. (2023), “The interplay between multiple control mechanisms in a host–parasitoid system: a discrete-time stage-structured modelling approach,” Journal of Biological Dynamics 17.1, p. 2241483.
Ackleh, A. S., Salceanu, P., and Veprauskas, A. (2021), “A nullcline approach to global stability in discrete-time predator–prey models,” Journal of Difference Equations and Applications 27.8, pp. 1120–1133.
Allen, L. J. and Driessche, P. van den (2008), “The basic reproduction number in some discrete-time epidemic models,” Journal of difference equations and applications 14.10-11, pp. 1127–1147.
Alston, D. G. (2011), “Pest Management Decistion-Making: The Economic-Injury Level Concept,”
Bale, J., Van Lenteren, J., and Bigler, F. (2008), “Biological control and sustainable food production,” Philosophical Transactions of the Royal Society B: Biological Sciences 363.1492, pp. 761–776.
Bellows, T. and Fisher, T. (1999), Handbook of biological control: principles and applications of biological control Academic Press.
Bellows, T. and Hassell, M. (1988), “The Dynamics of Age-Structured Host–Parasitoid Interactions,” The Journal of Animal Ecology, pp. 259–268.
Bernstein, C. (1986), “Density dependence and the stability of host-parasitoid systems,” Oikos, pp. 176–180.
Blayneh, K. W., Gumel, A. B., Lenhart, S., and Clayton, T. (2010), “Backward bifurcation and optimal control in transmission dynamics of West Nile virus,”
Bulletin of mathematical biology 72.4, pp. 1006–1028. Brauer, F. (2004), “Backward bifurcations in simple vaccination models,” Journal of Mathematical Analysis and Applications 298.2, pp. 418–431.
Briggs, C. J. (1993), “Competition among parasitoid species on a stage-structured host and its effect on host suppression,” The American Naturalist 141.3, pp. 372–397.
Castillo-Chavez, C. and Yakubu, A.-A. (2001), “Discrete-time SIS models with complex dynamics,” Nonlinear Analysis, Theory, Methods and Applications 47.7, pp. 4753–4762.
Crowe, K. M. and Cushing, J. (1994), “Optimal instar parasitization in a stage structured host-parasitoid model,” Natural Resource Modeling 8.2, pp. 119–138.
Cushing, J. M. and Diekmann, O. (2016), “The many guises of R0 (a didactic note),” Journal of theoretical biology 404, pp. 295–302.
Cushing, J. M. (1998), An introduction to structured population dynamics, SIAM.
Cushing, J., Martins, F., Pinto, A., and Veprauskas, A. (2017), “A bifurcation theorem for evolutionary matrix models with multiple traits,” Journal of Mathematical Biology 75.2, pp. 491–520.
Diekmann, O., Heesterbeek, J. A. P., and Roberts, M. G. (2010), “The construction of next-generation matrices for compartmental epidemic models,” Journal of the royal society interface 7.47, pp. 873–885.
Driessche, P. van den and Yakubu, A.-A. (2019), “Demographic population cycles and R_0 in discrete-time epidemic models,” Journal of Biological Dynamics 13.sup1, pp. 179–200.
Elaydi, S. and Yakubu, A.-A. (2002), “Global stability of cycles: Lotka-Volterra competition model with stocking,” The Journal of Difference Equations and Applications 8.6, pp. 537–549.
Elaydi, S. N. (2007), Discrete chaos: with applications in science and engineering, Chapman and Hall/CRC.
Elaydi, S. N. and Cushing, J. M. (2025), Discrete mathematical models in population biology: ecological, epidemic, and evolutionary dynamics, Springer Nature.
Garba, S. M., Gumel, A. B., and Bakar, M. A. (2008), “Backward bifurcations in dengue transmission dynamics,” Mathematical biosciences 215.1, pp. 11–25.
Guerrero-Flores, S., Osuna, O., and Villavicencio-Pulido, G. (2018), “Different types of backward bifurcations on account of an improvement in treatment efficiency,” Revista Integración 36.1, pp. 21–35.
Gumel, A. B. (2012), “Causes of backward bifurcations in some epidemiological models,” Journal of Mathematical Analysis and Applications 395.1, pp. 355–365.
Hadeler, K. P. and Van den Driessche, P. (1997), “Backward bifurcation in epidemic control,” Mathematical Biosciences 146.1, pp. 15–35.
He, M., Tang, S., and Cheke, R. A. (2020), “A Holling type II discrete switching host-parasitoid system with a nonlinear threshold policy for integrated pest management,” Discrete Dynamics in Nature and Society 2020.
Heinrichs, E., Mochida, O., et al. (1984), “From secondary to major pest status: the case of insecticide-induced rice brown planthopper, Nilaparvata lugens, resurgence.” Protection Ecology 7.2/3, pp. 201–218.
Henter, H. J. and Via, S. (1995), “The potential for coevolution in a host-parasitoid system. I. Genetic variation within an aphid population in susceptibility to a parasitic wasp,” Evolution 49.3, pp. 427–438.
Higley, L. G. (1986), “Economic injury levels in theory and practice,” Annu. Rev. Entomology 31, pp. 341–368.
Hochberg, M. E. and Holt, R. D. (1999), “The uniformity and density of pest exploitation as guides to success in biological control,” Theoretical approaches to biological control, pp. 71–88.
Hutson, V. (1990), “The existence of an equilibrium for permanent systems,” The Rocky Mountain Journal of Mathematics, pp. 1033–1040.
Jang, S.-J. (2007), “Allee effects in a discrete-time host-parasitoid model with stage structure in the host,” Discrete & Continuous Dynamical Systems-B 8.1, p. 145.
Jang, S. R.-J. (2008), “Backward bifurcation in a discrete SIS model with vaccination,” Journal of Biological Systems 16.04, pp. 479–494.
Jang, S. R.-J. and Yu, J.-L. (2011), “Dynamics of a discrete-time host–parasitoid system with cannibalism,” Journal of biological dynamics 5.5, pp. 419–435.
Jang, S. R.-J. and Yu, J.-L. (2012), “Discrete-time host–parasitoid models with pest control,” Journal of biological dynamics 6.2, pp. 718–739.
Kribs-Zaleta, C. M. and Velasco-Hernández, J. X. (2000), “A simple vaccination model with multiple endemic states,” Mathematical biosciences 164.2, pp. 183–201.
Li, Y., Xiang, C., and Tan, Y. (2025), “Bistability and Double-Peak Hormetic Effects of a Discrete-Time Pest Model,” Mathematical Methods in the Applied Sciences 48.17, pp. 15808–15824.
Liang, J., Tang, S., and Cheke, R. A. (2018), “A discrete host-parasitoid model with development of pesticide resistance and IPM strategies,” Journal of Biological Dynamics 12.1, pp. 1059–1078.
Liu, H., Li, Z., Gao, M., Dai, H., and Liu, Z. (2009), “Dynamics of a host–parasitoid model with Allee effect for the host and parasitoid aggregation,” Ecological Complexity 6.3, pp. 337–345.
Livadiotis, G., Assas, L., Dennis, B., Elaydi, S., and Kwessi, E. (2015), “A discrete-time host–parasitoid model with an Allee effect,” Journal of Biological Dynamics 9.1, pp. 34–51.
Marcinko, K. (2020), Mathematical analysis of host–parasitoid dynamics, University of Washington.
McKenzie, C. A. (1977), “On the ecology of Diaeretiella rapae (M’Intosh)”. PhD thesis. Adelaide,
Meissen, E. P. (2017), “Invading a Structured Population: A Bifurcation Approach”. PhD dissertation. The University of Arizona.
Mills, N. J. and Getz, W. M. (1996), “Modelling the biological control of insect pests: a review of host-parasitoid models,” Ecological modelling 92.2-3, pp. 121–143.
Mokni, K., Elaydi, S., Ch-Chaoui, M., and Eladdadi, A. (2020), “Discrete evolutionary population models: a new approach,” Journal of Biological Dynamics 14.1, pp. 454–478.
Salceanu, P. L. (2011), “Robust uniform persistence in discrete and continuous dynamical systems using Lyapunov exponents,” Math. Biosci. Eng 8.3, pp. 807–825.
Salceanu, P. L. (2013), “Robust uniform persistence in discrete and continuous nonautonomous systems,” Journal of Mathematical Analysis and Applications 398.2, pp. 487–500.
Salceanu, P. L. and Smith, H. L. (2009), “Lyapunov exponents and persistence in discrete dynamical systems,” Discrete Contin. Dyn. Syst. Ser. B 12.1, pp. 187–203.
Saphores, J.-D. M. (2000), “The economic threshold with a stochastic pest population: a real options approach,” American Journal of Agricultural Economics 82.3, pp. 541–555.
Sasaki, A. and Godfray, H. (1999), “A model for the coevolution of resistance and virulence in coupled host–parasitoid interactions,” Proceedings of the Royal Society of London. Series B: Biological Sciences 266.1418, pp. 455–463.
Schreiber, S. J. (2006), “Host-parasitoid dynamics of a generalized Thompson model,” Journal of Mathematical Biology 52.6, pp. 719–732.
Singh, A. (2020), “Analytical discrete-time models of insect population dynamics,”
Singh, A. (2021), “Fluctuations in population densities inform stability mechanisms in host-parasitoid interactions,” bioRxiv, pp. 2020–12.
Spataro, T. and Bernstein, C. (2004), “Combined effects of intraspecific competition and parasitoid attacks on the dynamics of a host population: a stage-structured model,” Oikos 105.1, pp. 148–158.
Stark, J. D., McIntyre, J. K., and Banks, J. E. (2020), “Population viability in a host-parasitoid system is mediated by interactions between population stage structure and life stage differential susceptibility to toxicants,” Scientific Reports 10.1, pp. 1–7.
Stejskal, V. (2003), “‘Economic Injury Level’and preventive pest control,” Journal of Pest Science 76.6, pp. 170–172.
Tang, S. and Cheke, R. A. (2008), “Models for integrated pest control and their biological implications,” Mathematical Biosciences 215.1, pp. 115–125.
Tang, S., Chen, L., et al. (2004), “Modelling and analysis of integrated pest management strategy,” Discrete and Continuous Dynamical Systems Series B 4, pp. 759–768.
Tang, S., Tang, G., and Cheke, R. A. (2010), “Optimum timing for integrated pest management: modelling rates of pesticide application and natural enemy releases,” Journal of Theoretical Biology 264.2, pp. 623–638.
Tang, S., Xiao, Y., and Cheke, R. A. (2008), “Multiple attractors of host–parasitoid models with integrated pest management strategies: Eradication, persistence and outbreak,” Theoretical population biology 73.2, pp. 181–197.
Tobin, P. C., Berec, L., and Liebhold, A. M. (2011), “Exploiting Allee effects for managing biological invasions,” Ecology letters 14.6, pp. 615–624.
Van den Driessche, P. and Yakubu, A.-A. (2019), “Disease extinction versus persistence in discrete-time epidemic models,” Bulletin of mathematical biology 81.11, pp. 4412–4446.
Van den Driessche, P. (2017), “Reproduction numbers of infectious disease models,” Infectious disease modelling 2.3, pp. 288–303.
Wang, W. (2006), “Backward bifurcation of an epidemic model with treatment,” Mathematical biosciences 201.1-2, pp. 58–71.
Wang, Z.-w. (2009), “Backward bifurcation in simple SIS model,” Acta Mathematicae Applicatae Sinica, English Series 25.1, pp. 127–136.
Wangari, I. M. and Stone, L. (2018), “Backward bifurcation and hysteresis in models of recurrent tuberculosis,” PloS one 13.3, e0194256.
White, S. M., Sait, S. M., and Rohani, P. (2007), “Population dynamic consequences of parasitised-larval competition in stage-structured host–parasitoid systems,” Oikos 116.7, pp. 1171–1185.
Xiang, C., Xiang, Z., Tang, S., and Wu, J. (2014a), “Discrete switching host-parasitoid models with integrated pest control,” International Journal of Bifurcation and Chaos 24.09, p. 1450114.
Xiang, C., Xiang, Z., and Yang, Y. (2014b), “Dynamic complexity of a switched host-parasitoid model with Beverton-Holt growth concerning integrated pest management,” Journal of Applied Mathematics 2014.1, p. 501423.
Xiang, L., Zhang, Y., and Huang, J. (2020), “Stability analysis of a discrete SIRS epidemic model with vaccination,” Journal of Difference Equations and Applications 26.3, pp. 309–327.
Yakubu, A.-A. (2010), “Introduction to Discrete-time Epidemic Models.” Modeling Paradigms and Analysis of Disease Trasmission Models, pp. 83–107.
Yakubu, A.-A. (2021), “A discrete-time infectious disease model for global pandemics,” Proceedings of the National Academy of Sciences 118.42, e2116845118.
Zhao, X.-Q. (2003), Dynamical systems in population biology, vol. 16. Springer.