Complex oscillatory patterns in a three-timescale model of a generalist predator and a specialist predator competing for a common prey

TL;DR

This paper models a three-timescale predator-prey system revealing complex oscillatory behaviors like MMOs, torus canards, and bursting patterns, providing new insights into ecological dynamics with multiple interacting timescales.

Contribution

It introduces a novel three-timescale population model exhibiting diverse oscillatory patterns, including behaviors not previously observed in such models.

Findings

Identification of relaxation oscillations, MMOs, and bursting patterns.

Discovery of torus canards and mixed-type torus canards in ecological models.

Analysis of bifurcations and transitions between different oscillatory regimes.

Abstract

In this paper, we develop and analyze a model that studies the interaction between a specialist predator, a generalist predator, and their common prey in a two-trophic ecosystem featuring three timescales. We assume that the prey operates on a faster timescale, while the specialist and generalist predators operate on slow and superslow timescales respectively. Treating the predation efficiency of the generalist predator as the primary varying parameter and the proportion of its diet formed by the prey species under study as the secondary parameter, we obtain a host of rich and interesting dynamics, including relaxation oscillations, mixed-mode oscillations (MMOs), subcritical elliptic bursting patterns, torus canards, and mixed-type torus canards. By grouping the timescales into two classes and using the timescale separation between classes, we apply one-fast/two-slow and two-fast/one-slow analysis techniques to gain insights about the dynamics. Using the geometric properties and flows of the singular subsystems, in combination with bifurcation analysis and numerical continuation of the full system, we classify the oscillatory dynamics and discuss the transitions from one type of dynamics to the other. The types of oscillatory patterns observed in this model are novel in population models featuring three-timescales; some of which qualitatively resemble natural cycles in small mammals and insects. Furthermore, oscillatory dynamics displaying torus canards, mixed-type torus canards, and MMOs experiencing a delayed loss of stability near one of the invariant sheets of the self-intersecting critical manifold before getting attracted to the adjacent attracting sheet of the critical manifold have not been previously reported in three-timescale models.