Difference between revisions of "Math 22 Natural Exponential Functions"

Limit Definition of ${\displaystyle e}$

 The irrational number ${\displaystyle e}$ is defined to be the limit:
 ${\displaystyle \lim _{x\to 0}(1+x)^{\frac {1}{x}}=e}$
 ${\displaystyle e\approx 2.71828182846}$

Compound Interest

 Let ${\displaystyle P}$ be the amount deposited, ${\displaystyle t}$ the number of years, ${\displaystyle A}$ the balance, 
 and ${\displaystyle r}$ the annual interest rate (in decimal form).
 1. Compounded ${\displaystyle n}$ times per year: ${\displaystyle A=P(1+{\frac {r}{n}})^{nt}}$
 2. Compounded continuously: ${\displaystyle A=Pe^{rt}}$

Exercises Find the balance in an account when $3000 is deposited for 10 years at an interest rate of 4%, compounded as follows.

a) Quarterly

Solution:
${\displaystyle A=3000(1+{\frac {0.04}{4}})^{(4)10}}$

a) Annually

Solution:
${\displaystyle A=3000(1+{\frac {0.04}{1}})^{(1)10}}$

a) Monthly

Solution:
${\displaystyle A=3000(1+{\frac {0.04}{12}})^{(12)10}}$

a) Daily

Solution:
${\displaystyle A=3000(1+{\frac {0.04}{365}})^{(365)10}}$

a) Continuously

Solution:
${\displaystyle A=Pe^{rt}=3000(e^{(0.04)(10)})}$

Present Value

${\displaystyle P={\frac {A}{(1+{\frac {r}{n}})^{nt}}}}$

Exercises How much money should be deposited in an account paying 5% interest compounded monthly in order to have a balance of $20000 after 5 years?

Solution:
This is present value problem. So
${\displaystyle P={\frac {A}{(1+{\frac {r}{n}})^{nt}}}={\frac {20000}{(1+{\frac {0.05}{12}})^{(12)(5)}}}}$

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