Dynamics analysis of a Filippov pest control model with time delay

•A Filippov prey–predator (pest-natural enemy) model with time delay is introduced to describe the IPM strategy with economic threshold.•The time delay represents the change of growth rate of the natural enemy before releasing it to eliminate pests.•Our findings show that, the time delay τ has a sig...

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Bibliographic Details
Published inCommunications in nonlinear science & numerical simulation Vol. 101; p. 105865
Main Authors Arafa, Ayman A., Hamdallah, Soliman A.A., Tang, Sanyi, Xu, Yong, Mahmoud, Gamal M.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.10.2021
Elsevier Science Ltd
Subjects
Crop production
Differential equations
Filippov system
Hopf bifurcation
IPM strategies
Mathematical models
Nonlinear equations
Parameters
Partial differential equations
Pest control
Pests
Sliding bifurcation
Sliding mode control
Systems stability
Time delay
Time lag
Pest control
Sliding bifurcation
IPM strategies
Time delay
Filippov system
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Summary:•A Filippov prey–predator (pest-natural enemy) model with time delay is introduced to describe the IPM strategy with economic threshold.•The time delay represents the change of growth rate of the natural enemy before releasing it to eliminate pests.•Our findings show that, the time delay τ has a significant impact on the Filippov system.•A non-trivial periodic solution bifurcates from the positive equilibria. The most critical factor for increasing crop production is the successful resistance of pests and pathogens which has massive impacts on global food security. Therefore, Filippov systems have been used to model and grasp control strategies for limited resources in Integrated Pest Management (IPM). Extensive studies have been done on these systems where the evolution is governed by a smooth set of ordinary differential equations (ODEs). As far as we know the time delay has not been considered in these systems, which we mean that a set of delay differential equations (DDEs). With this motivation, a Filippov prey–predator (pest–natural enemy) model with time delay is introduced in this paper, where the time delay represents the change of growth rate of the natural enemy before releasing it to feed on pests. The threshold conditions for the stability of the equilibria are derived by using time delay as a bifurcation parameter. It is shown that when the time delay parameter passes through some critical values, a periodic oscillation phenomenon appears through Hopf bifurcation. Further, by employing Filippov convex method we obtain the equation of sliding motion and address the sliding mode dynamics. Numerically, we demonstrate that the time delay plays a substantial role in discontinuity-induced bifurcation. More precisely, one can get boundary focus bifurcation from boundary node bifurcation through variation of the value of the time delay. Moreover, the time delay is used as a bifurcation parameter to obtain sliding–switching and sliding–grazing bifurcations. In conclusion, a Filippov system with time delay can give new insights into pest control models.
ISSN:1007-5704
1878-7274
DOI:10.1016/j.cnsns.2021.105865