Answer:
Part 1) [tex]t=11.610\ years[/tex]
Part 2) [tex]t=11.552\ years[/tex]
Step-by-step explanation:
Part 1) we know that
The compound interest formula is equal to
[tex]A=P(1+\frac{r}{n})^{nt}[/tex]
where
A is the Final Investment Value
P is the Principal amount of money to be invested
r is the rate of interest in decimal
t is Number of Time Periods
n is the number of times interest is compounded per year
in this problem we have
[tex]A=\$5,000\\P=\$2,500\\ r=6\%=6/100=0.06\\n=6[/tex]
substitute in the formula above
[tex]5,000=2,500(1+\frac{0.06}{6})^{6t}[/tex]
[tex]2=(1.01)^{6t}[/tex]
Apply log both sides
[tex]log(2)=log[(1.01)^{6t}][/tex]
[tex]log(2)=(6t)log(1.01)[/tex]
solve for t
[tex]t=log(2)/[6log(1.01)][/tex]
[tex]t=11.610\ years[/tex]
Part 2) we know that
The formula to calculate continuously compounded interest is equal to
[tex]A=P(e)^{rt}[/tex]
where
A is the Final Investment Value
P is the Principal amount of money to be invested
r is the rate of interest in decimal
t is Number of Time Periods
e is the mathematical constant number
we have
[tex]A=\$5,000\\P=\$2,500\\ r=6\%=6/100=0.06[/tex]
substitute in the formula above
[tex]5,000=2,500(e)^{0.06t}[/tex]
[tex]2=(e)^{0.06t}[/tex]
Apply ln both sides
[tex]ln(2)=ln[(e)^{0.06t}][/tex]
[tex]ln(2)=(0.06t)ln(e)[/tex]
[tex]ln(2)=(0.06t)[/tex]
[tex]t=ln(2)/(0.06)[/tex]
[tex]t=11.552\ years[/tex]
