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Study Guides > Mathematics for the Liberal Arts

Savings Annuities

Learning Outcomes

  • Calculate the balance on an annuity after a specific amount of time
  • Discern between compound interest, annuity, and payout annuity given a finance scenario
  • Use the loan formula to calculate loan payments, loan balance, or interest accrued on a loan
  • Determine which equation to use for a given scenario
  • Solve a financial application for time

Savings Annuity

For most of us, we aren’t able to put a large sum of money in the bank today. Instead, we save for the future by depositing a smaller amount of money from each paycheck into the bank. This idea is called a savings annuity. Most retirement plans like 401k plans or IRA plans are examples of savings annuities. Glass jar labeled An annuity can be described recursively in a fairly simple way. Recall that basic compound interest follows from the relationship

[latex]{{P}_{m}}=\left(1+\frac{r}{k}\right){{P}_{m-1}}[/latex]

For a savings annuity, we simply need to add a deposit, d, to the account with each compounding period:

[latex]{{P}_{m}}=\left(1+\frac{r}{k}\right){{P}_{m-1}}+d[/latex]

Taking this equation from recursive form to explicit form is a bit trickier than with compound interest. It will be easiest to see by working with an example rather than working in general.

Example

Suppose we will deposit $100 each month into an account paying 6% interest. We assume that the account is compounded with the same frequency as we make deposits unless stated otherwise. Write an explicit formula that represents this scenario.

Answer: In this example:

  • r = 0.06 (6%)
  • k = 12 (12 compounds/deposits per year)
  • d = $100 (our deposit per month)
Writing out the recursive equation gives [latex-display]{{P}_{m}}=\left(1+\frac{0.06}{12}\right){{P}_{m-1}}+100=\left(1.005\right){{P}_{m-1}}+100[/latex-display] Assuming we start with an empty account, we can begin using this relationship: [latex-display]P_0=0[/latex-display] [latex-display]P_1=(1.005)P_0+100=100[/latex-display] [latex-display]P_2=(1.005)P_1+100=(1.005)(100)+100=100(1.005)+100[/latex-display] [latex-display]P_3=(1.005)P_2+100=(1.005)(100(1.005)+100)+100=100(1.005)^2+100(1.005)+100[/latex-display] Continuing this pattern, after m deposits, we’d have saved: [latex-display]P_m=100(1.005)^{m-1}+100(1.005)^{m-2} +L+100(1.005)+100[/latex-display] In other words, after m months, the first deposit will have earned compound interest for m-1 months. The second deposit will have earned interest for -2 months. The last month's deposit (L) would have earned only one month's worth of interest. The most recent deposit will have earned no interest yet. This equation leaves a lot to be desired, though – it doesn’t make calculating the ending balance any easier! To simplify things, multiply both sides of the equation by 1.005: [latex-display]1.005{{P}_{m}}=1.005\left(100{{\left(1.005\right)}^{m-1}}+100{{\left(1.005\right)}^{m-2}}+\cdots+100(1.005)+100\right)[/latex-display] Distributing on the right side of the equation gives [latex-display]1.005{{P}_{m}}=100{{\left(1.005\right)}^{m}}+100{{\left(1.005\right)}^{m-1}}+\cdots+100{{(1.005)}^{2}}+100(1.005)[/latex-display] Now we’ll line this up with like terms from our original equation, and subtract each side [latex-display]\begin{align}&\begin{matrix}1.005{{P}_{m}}&=&100{{\left(1.005\right)}^{m}}+&100{{\left(1.005\right)}^{m-1}}+\cdots+&100(1.005)&{}\\{{P}_{m}}&=&{}&100{{\left(1.005\right)}^{m-1}}+\cdots+&100(1.005)&+100\\\end{matrix}\\&\\\end{align}[/latex-display] Almost all the terms cancel on the right hand side when we subtract, leaving [latex-display]1.005{{P}_{m}}-{{P}_{m}}=100{{\left(1.005\right)}^{m}}-100[/latex-display] Factor [latex]P_m[/latex] out of the terms on the left side. [latex-display]\begin{array}{c}P_m(1.005-1)=100{{\left(1.005\right)}^{m}}-100\\(0.005)P_m=100{{\left(1.005\right)}^{m}}-100\end{array}[/latex-display] Solve for Pm [latex-display]\begin{align}&0.005{{P}_{m}}=100\left({{\left(1.005\right)}^{m}}-1\right)\\&\\&{{P}_{m}}=\frac{100\left({{\left(1.005\right)}^{m}}-1\right)}{0.005}\\\end{align}[/latex-display] Replacing m months with 12N, where N is measured in years, gives [latex-display]{{P}_{N}}=\frac{100\left({{\left(1.005\right)}^{12N}}-1\right)}{0.005}[/latex-display] Recall 0.005 was r/k and 100 was the deposit d. 12 was k, the number of deposit each year.

Generalizing this result, we get the savings annuity formula.

Annuity Formula

[latex-display]P_{N}=\frac{d\left(\left(1+\frac{r}{k}\right)^{Nk}-1\right)}{\left(\frac{r}{k}\right)}[/latex-display]
  • PN is the balance in the account after N years.
  • d is the regular deposit (the amount you deposit each year, each month, etc.)
  • r is the annual interest rate in decimal form.
  • k is the number of compounding periods in one year.
If the compounding frequency is not explicitly stated, assume there are the same number of compounds in a year as there are deposits made in a year.
For example, if the compounding frequency isn’t stated:
  • If you make your deposits every month, use monthly compounding, k = 12.
  • If you make your deposits every year, use yearly compounding, k = 1.
  • If you make your deposits every quarter, use quarterly compounding, k = 4.
  • Etc.

When do you use this?

Annuities assume that you put money in the account on a regular schedule (every month, year, quarter, etc.) and let it sit there earning interest. Compound interest assumes that you put money in the account once and let it sit there earning interest.
  • Compound interest: One deposit
  • Annuity: Many deposits.

Examples

A traditional individual retirement account (IRA) is a special type of retirement account in which the money you invest is exempt from income taxes until you withdraw it. If you deposit $100 each month into an IRA earning 6% interest, how much will you have in the account after 20 years?

Answer: In this example,

d = $100 the monthly deposit
r = 0.06 6% annual rate
k = 12 since we’re doing monthly deposits, we’ll compound monthly
N = 20  we want the amount after 20 years
Putting this into the equation: [latex-display]\begin{align}&{{P}_{20}}=\frac{100\left({{\left(1+\frac{0.06}{12}\right)}^{20(12)}}-1\right)}{\left(\frac{0.06}{12}\right)}\\&{{P}_{20}}=\frac{100\left({{\left(1.005\right)}^{240}}-1\right)}{\left(0.005\right)}\\&{{P}_{20}}=\frac{100\left(3.310-1\right)}{\left(0.005\right)}\\&{{P}_{20}}=\frac{100\left(2.310\right)}{\left(0.005\right)}=\$46200 \\\end{align}[/latex-display] The account will grow to $46,200 after 20 years. Notice that you deposited into the account a total of $24,000 ($100 a month for 240 months). The difference between what you end up with and how much you put in is the interest earned. In this case it is $46,200 - $24,000 = $22,200.

This example is explained in detail here. https://youtu.be/quLg4bRpxPA  

Try It

A conservative investment account pays 3% interest. If you deposit $5 a day into this account, how much will you have after 10 years? How much is from interest?

Answer:

d = $5              the daily deposit r = 0.03           3% annual rate k = 365            since we’re doing daily deposits, we’ll compound daily N = 10             we want the amount after 10 years [latex-display]P_{10}=\frac{5\left(\left(1+\frac{0.03}{365}\right)^{365*10}-1\right)}{\frac{0.03}{365}}=21,282.07[/latex-display]

 Financial planners typically recommend that you have a certain amount of savings upon retirement.  If you know the future value of the account, you can solve for the monthly contribution amount that will give you the desired result. In the next example, we will show you how this works.

Example

You want to have $200,000 in your account when you retire in 30 years. Your retirement account earns 8% interest. How much do you need to deposit each month to meet your retirement goal?

Answer: In this example, we’re looking for d.

r = 0.08 8% annual rate
k = 12 since we’re depositing monthly
N = 30 30 years
P30 = $200,000 The amount we want to have in 30 years
In this case, we’re going to have to set up the equation, and solve for d. [latex-display]\begin{align}&200,000=\frac{d\left({{\left(1+\frac{0.08}{12}\right)}^{30(12)}}-1\right)}{\left(\frac{0.08}{12}\right)}\\&200,000=\frac{d\left({{\left(1.00667\right)}^{360}}-1\right)}{\left(0.00667\right)}\\&200,000=d(1491.57)\\&d=\frac{200,000}{1491.57}=\$134.09 \\\end{align}[/latex-display] So you would need to deposit $134.09 each month to have $200,000 in 30 years if your account earns 8% interest.

View the solving of this problem in the following video. https://youtu.be/LB6pl7o0REc
 

Solving For Time

We can solve the annuities formula for time, like we did the compounding interest formula, by using logarithms. In the next example we will work through how this is done.

Example

If you invest $100 each month into an account earning 3% compounded monthly, how long will it take the account to grow to $10,000?

Answer: This is a savings annuity problem since we are making regular deposits into the account.

d = $100 the monthly deposit
r = 0.03 3% annual rate
k = 12 since we’re doing monthly deposits, we’ll compound monthly
We don’t know N, but we want PN to be $10,000. Putting this into the equation: [latex]10,000=\frac{100\left({{\left(1+\frac{0.03}{12}\right)}^{N(12)}}-1\right)}{\left(\frac{0.03}{12}\right)}[/latex]                        Simplifying the fractions a bit [latex-display]10,000=\frac{100\left({{\left(1.0025\right)}^{12N}}-1\right)}{0.0025}[/latex-display] We want to isolate the exponential term, 1.002512N, so multiply both sides by 0.0025 [latex]25=100\left({{\left(1.0025\right)}^{12N}}-1\right)[/latex]                             Divide both sides by 100 [latex]0.25={{\left(1.0025\right)}^{12N}}-1[/latex]                                     Add 1 to both sides [latex]1.25={{\left(1.0025\right)}^{12N}}[/latex]                                        Now take the log of both sides [latex]\log\left(1.25\right)=\log\left({{\left(1.0025\right)}^{12N}}\right)[/latex]                              Use the exponent property of logs [latex]\log\left(1.25\right)=12N\log\left(1.0025\right)[/latex]                          Divide by 12log(1.0025) [latex]\frac{\log\left(1.25\right)}{12\log\left(1.0025\right)}=N[/latex]                                               Approximating to a decimal N = 7.447 years It will take about 7.447 years to grow the account to $10,000.

This example is demonstrated here: https://youtu.be/F3QVyswCzRo
 

Licenses & Attributions

CC licensed content, Original

CC licensed content, Shared previously

  • Annuities. Authored by: David Lippman. Located at: http://www.opentextbookstore.com/mathinsociety/. License: CC BY-SA: Attribution-ShareAlike.
  • Retirement. Authored by: Tax Credits. Located at: https://www.flickr.com/photos/76657755@N04/7027606047/. License: CC BY: Attribution.
  • Savings Annuities. Authored by: OCLPhase2's channel. License: CC BY: Attribution.
  • Savings annuities - solving for the deposit. Authored by: OCLPhase2's channel. License: CC BY: Attribution.
  • Question ID 6691, 6688. Authored by: Lippman,David. License: CC BY: Attribution. License terms: IMathAS Community License CC-BY + GPL.
  • Determining The Value of an Annuity. Authored by: Sousa, James (Mathispower4u.com). License: CC BY: Attribution.
  • Determining The Value of an Annuity on the TI84. Authored by: Sousa, James (Mathispower4u.com). License: CC BY: Attribution.