Applications of Systems of Equations 459
EXERCISE
- a. Use SOLVESYS or your computer software to solve the prey-predator
initial value problem
dx
dt = 2x - .5xy; x(O) = 2
dy
dt = -2y + xy; y(O) = 3 .5
on the interval [O, 4]. Assume that the unit of time is measured in years
and the unit of population is measured in thousands. What is the period,
T? What is the minimum and maximum populat ion of the prey, x, and the
predators, y? What is the average prey and predator population?
b. Solve the indiscriminate, constant-effort harvesting, prey-predator initial
value problem
dx
dt = 2x - .5xy - .3x; x(O) = 2
dy
dt = -2y + xy - .3y; y(O) = 3.5
on the interval [O, 4]. What is the period, T? How does this period compare
with the period for part a? What is the minimum and maximum population
for the prey and predators? How do these values compare with the correspond-
ing answers in part a? What is the average prey and predator population?
How do these values compare with the corresponding answers in part a?
Modified Prey-Predator Models
In this section, we will consider several modifications to the Volterra-Lotka
prey-predator model.
Internal Prey Competition Model First, suppose that in the absence
of a predator the prey population grows so rapidly that internal competition
within the prey population for important resources such as food and living
space becomes a factor. This internal competition can be modelled by chang-
ing the assumption of Malthusian population growth for the prey (assump-
tion 6 of the previous section) to logistic population growth. The resulting
prey-predator model with internal prey competition is
dx 2
dt = rx - Cx - H xy
(1)
dy
dt = -sy + Qxy
where r, H , C, s, and Q are positive constants.