Respuesta :
Answer:
1) 20%
2) Choice a.
Step-by-step explanation:
[tex]P(t)=10000(0.2)^t[/tex]
1) [tex]P(0)[/tex] is the population initially.
[tex]P(1)[/tex] is the population after a year.
[tex]\frac{P(1)}{P(0)}[/tex] represents the population increase factor.
So let's evaluate that fraction:
[tex]\frac{P(1)}{P(0)}[/tex]
[tex]\frac{10000(0.2)^1}{10000(0.2)^0}[/tex]
[tex]\frac{0.2^1}{0.2^0}=\frac{0.2}{1}=0.2[/tex]
0.2=20%
2) Let's figure out the population growth in terms of months instead of years.
[tex]P(t)=10000(0.2)^{t}[/tex]
We want t to represent months.
A full year is 12 months, in a full year we have that [tex]P(1)=10000(0.2)^1=10000(0.2)=2000[/tex]
So we want a new P such that [tex]P(12)=2000[/tex] since 12 months equals a year.
Let's look at the functions given to see which gives us this:
a) [tex]P(12)=10000(0.87449)^{12}=2000 \text{approximately}[/tex]
b) [tex]P(12)=10000(0.87449)^{12(12)}=0 \text{ approximately}[/tex]
c) [tex]P(12)=10000(0.87449)^{\frac{1}{12}}=9889 \text{approximately}[/tex]
d) [tex]P(12)=10000(0.87449)^{12+12}=400 \text{approximately}[/tex]
So a is the function we want.
Also another way to look at this:
[tex]P(t)=10000(.2)^t[/tex] where [tex]t[/tex] is in years.
[tex]P(t)=10000(.2^\frac{1}{12})^t[/tex] where [tex]t[/tex] is in months.
And [tex].2^\frac{1}{12}=0.874485 \text{approximately}[/tex]
