To model this situation, we are going to use the decay formula: [tex]A=Pe^{rt}[/tex]
where
[tex]A[/tex] is the final pupolation
[tex]P[/tex] is the initial population
[tex]e[/tex] is the Euler's constant
[tex]r[/tex] is the decay rate
[tex]t[/tex] is the time in years
A. We know for our problem that the initial population is 1,250, so [tex]P=1250[/tex]; we also know that after a year the population is 1000, so [tex]A=1000[/tex] and [tex]t=1[/tex]. Lets replace those values in our formula to find [tex]r[/tex]:
[tex]A=Pe^{rt}[/tex]
[tex]1000=1250e^{r}[/tex]
[tex]e^{r}= \frac{1000}{1250} [/tex]
[tex]e^{r}= \frac{4}{5} [/tex]
[tex]ln(e^{r})=ln( \frac{4}{5} )[/tex]
[tex]r=ln( \frac{4}{5} )[/tex]
[tex]r=-02231[/tex]
Now that we have [tex]r[/tex], we can write a function to model this scenario:
[tex]A(t)=1250e^{-0.2231t}[/tex].
B. Here we are going to use a graphing utility to graph the function we derived in the previous point. Please check the attached image.
C.
- The function is decreasing
- The function doe snot have a x-intercept
- The function has a y-intercept at (0,1250)
- Since the function is decaying, it will have a maximum at t=0:
[tex]A(0)=1250e^{(-0.2231)(0)[/tex]
[tex]A_{0}=1250e^{0}[/tex]
[tex]A_{0}=1250[/tex]
- Over the interval [0,10], the function will have a minimum at t=10:
[tex]A(10)=1250e^{(-0.2231)(10)[/tex]
[tex]A_{10}=134.28[/tex]
D. To find the rate of change of the function over the interval [0,10], we are going to use the formula: [tex]m= \frac{A(0)-A(10)}{10-0} [/tex]
where
[tex]m[/tex] is the rate of change
[tex]A(10)[/tex] is the function evaluated at 10
[tex]A(0)[/tex] is the function evaluated at 0
We know from previous calculations that [tex]A(10)=134.28[/tex] and [tex]A(0)=1250[/tex], so lets replace those values in our formula to find [tex]m[/tex]:
[tex]m= \frac{134.28-1250}{10-0} [/tex]
[tex]m= \frac{-1115.72}{10} [/tex]
[tex]m=-111.572[/tex]
We can conclude that the rate of change of the function over the interval [0,10] is -111.572.
