In this case, we’re going to have to set up the equation, and solve for [latex]d[/latex].

[latex]\begin{align}&500,000=\frac{d\left(1-{{\left(1+\frac{0.08}{12}\right)}^{-30(12)}}\right)}{\left(\frac{0.08}{12}\right)}\\&500,000=\frac{d\left(1-{{\left(1.00667\right)}^{-360}}\right)}{\left(0.00667\right)}\\&500,000=d(136.232)\\&d=\frac{500,000}{136.232}=\$3670.21 \\\end{align}[/latex]

You would be able to withdraw [latex]$3,670.21[/latex] each month for [latex]30[/latex] years.

A detailed walkthrough of this example can be viewed here.

You can view the transcript for “Payout annuity – solve for withdrawal” here (opens in new window).

Note: This video uses [latex]k[/latex] for [latex]n[/latex] and [latex]N[/latex] for [latex]t[/latex].

[latex]\begin{array}{r@{\hfill}l}
d=\text{unknown} && \\
r=0.04 && \text{4% annual rate} \\
n=1 && \text{since we're doing annual scholarships} \\
t=20 && \text{20 years} \\
P_0=100,000 && \text{we're starting with } \$100,000 \\
\end{array}[/latex]

[latex]100,000=\frac{d\left(1-\left(1+\frac{0.04}{1}\right)^{-20*1}\right)}{\frac{0.04}{1}}[/latex]

Solving for [latex]d[/latex] gives [latex]$7,358.18[/latex] each year that they can give in scholarships. It is worth noting that usually donors instead specify that only interest is to be used for scholarship, which makes the original donation last indefinitely. If this donor had specified that, [latex]$100,000(0.04) = $4,000[/latex] a year would have been available.

In this case, we’re going to have to set up the equation, and solve for [latex]d[/latex].

[latex]\begin{align}&140,000=\frac{d\left(1-{{\left(1+\frac{0.06}{12}\right)}^{-30(12)}}\right)}{\left(\frac{0.06}{12}\right)}\\&140,000=\frac{d\left(1-{{\left(1.005\right)}^{-360}}\right)}{\left(0.005\right)}\\&140,000=d(166.792)\\&d=\frac{140,000}{166.792}=\$839.37 \\\end{align}[/latex]

You will make payments of [latex]$839.37[/latex] per month for [latex]30[/latex] years.

You’re paying a total of [latex]$302,173.20[/latex] to the loan company: [latex]$839.37[/latex] per month for [latex]360[/latex] months. You are paying a total of [latex]$302,173.20 - $140,000 = $162,173.20[/latex] in interest over the life of the loan.

View more about this example here.

You can view the transcript for “Calculating payment on a home loan” here (opens in new window).

Note: This video uses [latex]k[/latex] for [latex]n[/latex] and [latex]N[/latex] for [latex]t[/latex].

[latex]\begin{array}{r@{\hfill}l}
d= && \text{unknown}\\
r=0.16 && \text{16% annual rate} \\
n=12 && \text{since we're making monthly payments} \\
t=2 && \text{2 years to repay} \\
P_0=3,000 && \text{we're starting with a } \$3,000 \text{ loan} \\
\end{array}[/latex]

[latex]\begin{array}{c}3000=\frac{{d}\left(1-\left(1+\frac{0.06}{12}\right)^{-2*12}\right)}{\frac{0.16}{12}}\\\\3000=20.42d\end{array}[/latex]

Solve for d to get monthly payments of [latex]$146.89[/latex]. Two years to repay means [latex]$146.89(24) = $3525.36[/latex] in total payments. This means Janine will pay [latex]$3525.36 - $3000 = $525.36[/latex] in interest.