Permanence and universal classification of discrete-time competitive systems via the carrying simplex

Abstract: We study the permanence and impermanence for discrete-time Kolmogorov systems admitting a carrying simplex. Sufficient conditions to guarantee permanence and impermanence are provided based on the existence of a carrying simplex. Particularly, for low-dimensional systems, permanence and impermanence can be determined by boundary fixed points. For a class of competitive systems whose fixed points are determined by linear equations, there always exists a carrying simplex. We provide a universal classification vi… Show more

“…To be more explicit, when ϕ varies in [0, 1], system (4.1) enjoys different dynamic features: the orbit emanating from initial value x 0 = (0.5, 0.6, 0.4) for the Poincaré map S tends to the heteroclinic cycle Γ(see Figure 4) → invariant closed curves (see Figure 6 and Figure 7) → the positive fixed point (see Figure 8-12) → the interior fixed point of coordinate plane {x 2 = 0} (see Figure 13) → the interior fixed point of x 1 -axis (see Figure 14) → the interior fixed point of the coordinate plane {x 3 = 0} (see Figure 15) → the interior fixed point of x 2 -axis (see Figure 16) → the trivial fixed point O (see Figure 17). From these numerical examples, one can see that the dynamic features and patterns generated by system (4.1) are much richer , which are different from concrete discrete-time competitive maps analyzed in [6,7,13,14].…”

“…Hence, it suffices to investigate the dynamics of the discrete-time system {S n } n≥0 . However, compared to the concrete discrete-time competitive maps discussed in [4,6,7,13,14,16], there is no explicit expression of the Poincaré map S for system (1.2). This makes the research much more difficult and complicated on the dynamics of system (1.2).…”

Heteroclinic Cycles of A Symmetric May-Leonard Competition Model with Seasonal Succession

“…To be more explicit, when ϕ varies in [0, 1], system (4.1) enjoys different dynamic features: the orbit emanating from initial value x 0 = (0.5, 0.6, 0.4) for the Poincaré map S tends to the heteroclinic cycle Γ(see Figure 4) → invariant closed curves (see Figure 6 and Figure 7) → the positive fixed point (see Figure 8-12) → the interior fixed point of coordinate plane {x 2 = 0} (see Figure 13) → the interior fixed point of x 1 -axis (see Figure 14) → the interior fixed point of the coordinate plane {x 3 = 0} (see Figure 15) → the interior fixed point of x 2 -axis (see Figure 16) → the trivial fixed point O (see Figure 17). From these numerical examples, one can see that the dynamic features and patterns generated by system (4.1) are much richer , which are different from concrete discrete-time competitive maps analyzed in [6,7,13,14].…”

“…Hence, it suffices to investigate the dynamics of the discrete-time system {S n } n≥0 . However, compared to the concrete discrete-time competitive maps discussed in [4,6,7,13,14,16], there is no explicit expression of the Poincaré map S for system (1.2). This makes the research much more difficult and complicated on the dynamics of system (1.2).…”

Heteroclinic Cycles of A Symmetric May-Leonard Competition Model with Seasonal Succession

“…n = 1) competitive maps admitting a carrying simplex, there is a globally attracting positive fixed point as the carrying simplex, so the dynamics is trivial. For 2D competitive maps admitting a carrying simplex, every trajectory also converges to a fixed point (see [11]), because the map restricted to the one-dimensional carrying simplex is a homeomorphism. For 3D competitive maps admitting a carrying simplex, nontrivial dynamics such as Neimark-Sacker bifurcations and heteroclinic cycles can occur (see, for example, [8,9,10,11,12]).…”

“…For 2D competitive maps admitting a carrying simplex, every trajectory also converges to a fixed point (see [11]), because the map restricted to the one-dimensional carrying simplex is a homeomorphism. For 3D competitive maps admitting a carrying simplex, nontrivial dynamics such as Neimark-Sacker bifurcations and heteroclinic cycles can occur (see, for example, [8,9,10,11,12]). Neimark-Sacker bifurcation is the birth of an invariant cycle from a fixed point in discrete-time systems, and either all orbits are periodic, or all orbits are dense on the invariant cycle (in this case, it is called a quasiperiodic curve).…”

Chaotic attractors in the four-dimensional Leslie–Gower competition model

“…However, for most competitive discrete-time models on R n + , one can usually find a forward invariant and globally attracting hyperrectangle [0, u] with u 0 (see [9]), such as the Ricker map (2) (see [8]). Thus, in this note, we try to study the global stability of the Ricker map (2) in Gyllenberg et al's class 33 restricted to a forward invariant hyperrectangle directly without constructing a monotone region by the method in [1].…”

A note on global stability of three-dimensional Ricker models