Answer:
a) The recurrence formula is [tex]P_n = \frac{109}{100}P_{n-1}[/tex].
b) The general formula for the population of Tacoma is
[tex]P_n = \left(\frac{109}{100}\right)^nP_{0}[/tex].
c) In 2016 the approximate population of Tacoma will be 794062 people.
d) The population of Tacoma should exceed the 400000 people by the year 2009.
Step-by-step explanation:
a) We have the population in the year 2000, which is 200 000 people. Let us write [tex]P_0 = 200 000[/tex]. For the population in 2001 we will use [tex]P_1[/tex], for the population in 2002 we will use [tex]P_2[/tex], and so on.
In the following year, 2001, the population grow 9% with respect to the previous year. This means that [tex]P_0[/tex] is equal to [tex]P_1[/tex] plus 9% of the population of 2000. Notice that this can be written as
[tex]P_1 = P_0 + (9/100)*P_0 = \left(1-\frac{9}{100}\right)P_0 = \frac{109}{100}P_0[/tex].
In 2002, we will have the population of 2001, [tex]P_1[/tex], plus the 9% of [tex]P_1[/tex]. This is
[tex]P_2 = P_1 + (9/100)*P_1 = \left(1-\frac{9}{100}\right)P_1 = \frac{109}{100}P_1[/tex].
So, it is not difficult to notice that the general recurrence is
[tex]P_n = \frac{109}{100}P_{n-1}[/tex].
b) In the previous formula we only need to substitute the expression for [tex]P_{n-1}[/tex]:
[tex]P_{n-1} = \frac{109}{100}P_{n-2}[/tex].
Then,
[tex]P_n = \left(\frac{109}{100}\right)^2P_{n-2}[/tex].
Repeating the procedure for [tex]P_{n-3}[/tex] we get
[tex]P_n = \left(\frac{109}{100}\right)^3P_{n-3}[/tex].
But we can do the same operation n times, so
[tex]P_n = \left(\frac{109}{100}\right)^nP_{0}[/tex].
c) Recall the notation we have used:
[tex]P_{0}[/tex] for 2000, [tex]P_{1}[/tex] for 2001, [tex]P_{2}[/tex] for 2002, and so on. Then, 2016 is [tex]P_{16}[/tex]. So, in order to obtain the approximate population of Tacoma in 2016 is
[tex]P_{16} = \left(\frac{109}{100}\right)^{16}P_{0} = (1.09)^{16}P_0 = 3.97\cdot 200000 \approx 794062[/tex]
d) In this case we want to know when [tex]P_n>400000[/tex], which is equivalent to
[tex] (1.09)^{n}P_0>400000[/tex].
Substituting the value of [tex]P_0[/tex], we get
[tex] (1.09)^{n}200000>400000[/tex].
Simplifying the expression:
[tex] (1.09)^{n}>2[/tex].
So, we need to find the value of [tex]n[/tex] such that the above inequality holds.
The easiest way to do this is take logarithm in both hands. Then,
[tex]n\ln(1.09)>\ln 2[/tex].
So, [tex]n>\frac{\ln 2}{\ln(1.09)} = 8.04323172693 [/tex].
So, the population of Tacoma should exceed the 400 000 by the year 2009.
Answer:
a) P(n)=1.09^n*P(0)
b) P(n)=200k*(1.09*1.09*...*1.09) (n-times)
c) 764k
d) By the year of 2009
Step-by-step explanation:
a) We can write down the formula of Tacoma population as below:
[tex]P(n)=1.09^n*P(0)[/tex]
Where:
n is the last two digits of the year.
P(0)=200k
b) This formula can be written as below to be more explicit:
[tex]P(n)=200k*(1.09*1.09*...*1.09) (n-times)[/tex]
c) Tacoma Population in 2016 is:
[tex]P(16)=1.09^{16}*200k=794k[/tex]
d) When the value of (1.09)^n exceeds 2
[tex](1.09)^n\geq 2\\n\geq 9[/tex]
