Logistic Growth Model
Part 2: Equilibria
- The interactive figure below shows a direction field for the logistic differential equation
as well as a graph of the slope function, f(P) = r P (1 - P/K). Click on the left-hand figure to generate solutions of the logistic equation for various starting populations P(0). [Note: The vertical coordinate of the point at which you click is considered to be P(0). The horizontal (time) coordinate is ignored.]
- Explain why P(t) = 0 is a solution. A constant solution
is called an equilibrium.
- The logistic equation has another equilibrium, i.e.,
a solution of the form P(t) = constant. What is the constant? Explain how you know from the differential equation that this function is a solution.
- If the starting population P(0) is greater than K, what can you say about the solution P(t)? What do you see in the differential equation that confirms this behavior?
- If the starting population P(0) is less than than K, what can you say about the solution P(t)? What do you see in the differential equation that confirms this behavior?
- Why is carrying capacity an appropriate name for K?
An equilibrium solution P = c
is called stable if any solution P(t) that starts near P = c
stays near it. The equilibrium P = c is called asymptotically
stable if any solution P(t) that starts near P = c actually
converges to it -- that is,
If an equilibrium is not stable, it
is called unstable. This means there is at least one solution that starts
near the equilibrium and runs away from it.
- Is the equilibrium solution
P = 0 stable or unstable? If stable, is it also asymptotically stable?
Explain.
- Is the equilibrium solution
you found in step 3 stable or unstable? If stable, is it also asymptotically
stable? Explain.
