Respuesta :
Answer:
(a) The future value after 9 years is $7142.49.
(b) The effective rate is [tex]r_E=4.759 \:{\%}[/tex].
(c) The time to reach $13,000 is 21.88 years.
Step-by-step explanation:
The definition of Continuous Compounding is
If a deposit of [tex]P[/tex] dollars is invested at a rate of interest [tex]r[/tex] compounded continuously for [tex]t[/tex] years, the compound amount is
[tex]A=Pe^{rt}[/tex]
(a) From the information given
[tex]P=4700[/tex]
[tex]r=4.65\%=\frac{4.65}{100} =0.0465[/tex]
[tex]t=9 \:years[/tex]
Applying the above formula we get that
[tex]A=4700e^{0.0465\cdot 9}\\A=7142.49[/tex]
The future value after 9 years is $7142.49.
(b) The effective rate is given by
[tex]r_E=e^r-1[/tex]
Therefore,
[tex]r_E=e^{0.0465}-1=0.04759\\r_E=4.759 \:{\%}[/tex]
(c) To find the time to reach $13,000, we must solve the equation
[tex]13000=4700e^{0.0465\cdot t}[/tex]
[tex]4700e^{0.0465t}=13000\\\\\frac{4700e^{0.0465t}}{4700}=\frac{13000}{4700}\\\\e^{0.0465t}=\frac{130}{47}\\\\\ln \left(e^{0.0465t}\right)=\ln \left(\frac{130}{47}\right)\\\\0.0465t\ln \left(e\right)=\ln \left(\frac{130}{47}\right)\\\\0.0465t=\ln \left(\frac{130}{47}\right)\\\\t=\frac{\ln \left(\frac{130}{47}\right)}{0.0465}\approx21.88[/tex]
