Math  /  Calculus

QuestionFour thousand dollars is deposited into a savings account at 4.5%4.5 \% interest compounded continuously. (a) What is the formula for A(t)A(t), the balance after tt years? (b) What differential equation is satisfied by A(t)A(t), the balance after tt years? (c) How much money will be in the account after 9 years? (d) When will the balance reach $8000\$ 8000 ? (e) How fast is the balance growing when it reaches $8000\$ 8000 ? (c) $5997.21\$ 5997.21 (Round to the nearest cent as needed.) (d) After \square years the balance will reach $8000\$ 8000. (Round to one decimal place as needed.)

Studdy Solution

STEP 1

1. The initial deposit is $4000.
2. The interest rate is \(4.5\%\) compounded continuously.
3. The formula for continuous compounding is known.
4. We need to solve for multiple parts: formula, differential equation, future value, time to reach a certain balance, and growth rate at a specific balance.

STEP 2

1. Derive the formula for A(t) A(t) .
2. Determine the differential equation for A(t) A(t) .
3. Calculate the balance after 9 years.
4. Determine when the balance will reach 8000.<br/>5.Calculatethegrowthratewhenthebalanceis8000.<br />5. Calculate the growth rate when the balance is 8000.

STEP 3

The formula for the balance with continuous compounding is given by: A(t)=Pert A(t) = P e^{rt} where P P is the principal amount, r r is the interest rate, and t t is the time in years.
For this problem, P=4000 P = 4000 and r=0.045 r = 0.045 .
Thus, the formula becomes: A(t)=4000e0.045t A(t) = 4000 e^{0.045t}

STEP 4

The differential equation for A(t) A(t) is derived from the fact that the rate of change of the balance is proportional to the current balance: dAdt=rA \frac{dA}{dt} = rA
Substituting the given interest rate: dAdt=0.045A \frac{dA}{dt} = 0.045A

STEP 5

To find the balance after 9 years, substitute t=9 t = 9 into the formula: A(9)=4000e0.045×9 A(9) = 4000 e^{0.045 \times 9}
Calculate: A(9)=4000e0.4054000×1.4995997.21 A(9) = 4000 e^{0.405} \approx 4000 \times 1.499 \approx 5997.21

STEP 6

To find when the balance reaches $8000, solve the equation: \[ 8000 = 4000 e^{0.045t} \]
Divide both sides by 4000: 2=e0.045t 2 = e^{0.045t}
Take the natural logarithm of both sides: ln(2)=0.045t \ln(2) = 0.045t
Solve for t t : t=ln(2)0.0450.6930.04515.4 t = \frac{\ln(2)}{0.045} \approx \frac{0.693}{0.045} \approx 15.4

STEP 7

The growth rate when the balance is $8000 is given by the derivative: \[ \frac{dA}{dt} = 0.045A \]
Substitute A=8000 A = 8000 : dAdt=0.045×8000=360 \frac{dA}{dt} = 0.045 \times 8000 = 360
The solutions are: (a) A(t)=4000e0.045t A(t) = 4000 e^{0.045t} (b) dAdt=0.045A \frac{dA}{dt} = 0.045A (c) 5997.21 (d) After \( 15.4 \) years the balance will reach 8000. (e) The balance is growing at 360peryearwhenitreaches360 per year when it reaches 8000.

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