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Q1. Consider the Rosenzweig-MacArthur predator-prey model

where N is the prey density and P is the predator density.

(a)     What are nullclines of N and P?

(b)    What are equilibria of N and P?

(c)     Show the parameter condition in which an internal equilibrium (i.e., N,¯ P >¯ 0) is stable.

(d)    Describe in words how eutrophication (i.e., increasing K) and harvesting (i.e., increasing d) in this model affect the stability of the internal equilibrium.

(e)     Derive an analytical solution of when a = 0.

   (f)      Consider the Lotka-Volterra predator-prey model (i.e., K →∞ and h = 0 in the Rosenzweig-MacArthur model). Using the model and R, plot trajectories (P vs. N) given parameter values              r = 1, a = 2, c = 0.5, and d = 0.1 with the initial condition N(0) = 0.2 and P(0) = 0.5, from t = 0 to t = 200. Repeat for N(0) = 0.5 and N(0) = 1.

  ( g)    Derive an analytical solution of   (a)     of the Lotka-Volterra predator-prey model. of the Lokta-Volterra Preditor-Prey Model. How does the analytical solution help explain the behaviour in the graphs of (f)?

Q2. Consider the Lotka-Volterra competition model

where N_i is the density of competing species i (i = 1,2).

(a)     What are nullclines of N₁ and N₂?

(b)    What are equilibria of N₁ and N₂?

(c)     Show the parameter condition in which an internal equilibrium (i.e., N^¯₁,N^¯₂ > 0) is stable.

(d)    Show the Jacobian matrix of the model.

(e)     Calculate the Jacobian matrix of the model at the internal equilibrium.

(f)      When r₁ = r₂ = 1,α₁₁ = α₂₂ = 1, and α₁₂ = α₂₁ = 0.5, calculate eigenvalues and eigenvectors.

(g)     Explain the difference between the eigenvectors and nullclines.

Q3. Consider the following model,

where x and y are concentrations of chemical substances.

(a)     What are nullclines of x and y?

(b)    What are equilibria of x and y?

(c)     Show the Jacobian matrix of the model.

(d)    Calculate the Jacobian matrix of the model at an internal equilibrium (i.e.,x,¯ y >¯ 0).

(e)     Calculate the trace and determinant of the Jacobian matrix at the internalequilibrium.

Show the parameter condition in which the internal equilibrium is unstable.

Q4. Consider the following model

where x, y, and z are scaled variables and can be negative. The parameters, σ,r, and b, are positive.

(a)     What are nullclines of x, y, and z?

(b)    What are equilibria of x, y, and z?

(c)     Show the Jacobian matrix of the model.

(d)    Show the characteristic polynomial.

(e)     Calculate the Jacobian matrix of the model at an equilibrium at the origin(i.e., ¯x = ¯y = ¯z = 0).

(f)      Show the parameter condition in which the equilibrium at the origin is unstable.

A3_2021_MATH3070_1_

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The post Describe in words how eutrophication (i.e., increasing K) and harvesting (i.e., increasing d) in this model affect the stability of the internal equilibrium. appeared first on Apax Researchers.