3.2: Simple and Compound Interest

We have to work with money every day. While balancing your checkbook or calculating your monthly expenditures on espresso requires only arithmetic, when we start saving, planning for retirement, or need a loan, we need more mathematics. This section will show you how to solve these types of problems by hand. At the end of the section, there is a video and a calculator you can use to solve these problems as well.

 

Learning Objectives

The leaning objectives for this section include:

  1. Calculate one-time simple interest, and simple interest over time
  2. Calculate compound interest

1. Simple Interest

Discussing interest starts with the principal, or amount your account starts with. This could be a starting investment, or the starting amount of a loan. Interest, in its most simple form, is calculated as a percent of the principal. For example, if you borrowed $100 from a friend and agree to repay it with 5% interest, then the amount of interest you would pay would just be 5% of 100: $100(0.05) = $5. The total amount you would repay would be $105, the original principal plus the interest.

four rolled-up dollar bills seeming to grow out of dirt, with a miniature rake lying in between them

Simple One-time Interest

[latex]\begin{align}&I={{P}_{0}}r\\& \\&A={{P}_{0}}+I\\&A={{P}_{0}}+{{P}_{0}}r\\&A={{P}_{0}}(1+r)\\\end{align}[/latex]

 

  • I is the interest
  • A is the end amount: principal plus interest
  • [latex]\begin{align}{{P}_{0}}\\\end{align}[/latex] is the principal (starting amount)
  • r is the interest rate (in decimal form. Example: 5% = 0.05)

Examples

A friend asks to borrow $300 and agrees to repay it in 30 days with 3% interest. How much interest (simple) will you earn?

The following video works through this example in detail.

 

One-time simple interest is only common for extremely short-term loans. For longer term loans, it is common for interest to be paid on a daily, monthly, quarterly, or annual basis. In that case, interest would be earned regularly.

For example, bonds are essentially a loan made to the bond issuer (a company or government) by you, the bond holder. In return for the loan, the issuer agrees to pay interest, often annually. Bonds have a maturity date, at which time the issuer pays back the original bond value.

Exercises

Suppose your city is building a new park, and issues bonds to raise the money to build it. You obtain a $1,000 bond that pays 5% interest annually that matures in 5 years. How much interest will you earn?

Further explanation about solving this example can be seen here.

We can generalize this idea of simple interest over time.

Simple Interest over Time

[latex]\begin{align}&I={{P}_{0}}rt\\& \\&A={{P}_{0}}+I\\&A={{P}_{0}}+{{P}_{0}}rt\\&={{P}_{0}}(1+rt)\\\end{align}[/latex]

  • I is the interest
  • A is the end amount: principal plus interest
  • [latex]\begin{align}{{P}_{0}}\\\end{align}[/latex] is the principal (starting amount)
  • r is the interest rate in decimal form
  • t is time

The units of measurement (years, months, etc.) for the time should match the time period for the interest rate.

 

APR – Annual Percentage Rate

Interest rates are usually given as an annual percentage rate (APR) – the total interest that will be paid in the year. If the interest is paid in smaller time increments, the APR will be divided up.

For example, a 6% APR paid monthly would be divided into twelve 0.5% payments.
[latex]6\div{12}=0.5[/latex]

A 4% annual rate paid quarterly would be divided into four 1% payments.
[latex]4\div{4}=1[/latex]

Example

Treasury Notes (T-notes) are bonds issued by the federal government to cover its expenses. Suppose you obtain a $1,000 T-note with a 4% annual rate, paid semi-annually, with a maturity in 4 years. How much interest will you earn?

This video explains the solution.

Try It Now

A loan company charges $30 interest for a one month loan of $500. Find the annual interest rate they are charging.

2. Compound Interest

With simple interest, we were assuming that we pocketed the interest when we received it. In a standard bank account, any interest we earn is automatically added to our balance, and we earn interest on that interest in future years. This reinvestment of interest is called compounding.

TIME VALUE OF MONEY CALCULATOR

The following Time Value of Money Solver application/calculator will be a helpful tool in checking your answers:

The Time Value of Money Solver asks you to provide N, I%, PV, PMT, FV, P/Y, and C/Y.

N is the number of years, i% is the interest rate as a number (not a decimal), PV is the present value or P0, PMT is the payment each period (if there is no payment, then put in zero), FV is the future value or A, P/Y is periods per year (so if there is monthly compounding, this would be 12), and C/Y is how often compounding occurs (so if compounded quarterly, then put in 4). Note, that P/Y and C/Y will be the same for any problem you will see in this course. Lastly, PV and FV always have opposite signs (if PV is positive, FV will be negative)

Here is a video walking you through one of these types of problems:

a row of gold coin stacks. From left to right, they grown from one coin, to two, to four, ending with a stack of 32 coins

Suppose that we deposit $1000 in a bank account offering 3% interest, compounded monthly. How will our money grow?

The 3% interest is an annual percentage rate (APR) – the total interest to be paid during the year. Since interest is being paid monthly, each month, we will earn [latex]\frac{3%}{12}[/latex]= 0.25% per month.

In the first month,

  • P0 = $1000
  • r = 0.0025 (0.25%)
  • I = $1000 (0.0025) = $2.50
  • A = $1000 + $2.50 = $1002.50

In the first month, we will earn $2.50 in interest, raising our account balance to $1002.50.

 

In the second month,

  • P0 = $1002.50
  • I = $1002.50 (0.0025) = $2.51 (rounded)
  • A = $1002.50 + $2.51 = $1005.01

Notice that in the second month we earned more interest than we did in the first month. This is because we earned interest not only on the original $1000 we deposited, but we also earned interest on the $2.50 of interest we earned the first month. This is the key advantage that compounding interest gives us.

Calculating out a few more months gives the following:

Month Starting balance Interest earned Ending Balance
1 1000.00 2.50 1002.50
2 1002.50 2.51 1005.01
3 1005.01 2.51 1007.52
4 1007.52 2.52 1010.04
5 1010.04 2.53 1012.57
6 1012.57 2.53 1015.10
7 1015.10 2.54 1017.64
8 1017.64 2.54 1020.18
9 1020.18 2.55 1022.73
10 1022.73 2.56 1025.29
11 1025.29 2.56 1027.85
12 1027.85 2.57 1030.42

 

CALCULATOR: See if you can recreate the Ending Balance column using the calculator (Time Value of Money Solver)

For example, Month 1, starting balance of 1000 means you would put the following into the calculator:

N=1/12 (because we are only looking at 1 month and this box is the number of years)

I=3 (interest rate of 3%)

PV=1000 (the money we started with)

PMT=0 (there were no regular, recurring payments)

FV = (what we are solving for) – push this button and make sure it matches the above table (note that it will be negative because PV and FV are always opposite signs)

P/Y=12

C/Y=12

FORMULA: We want to simplify the process for calculating compounding, because creating a table like the one above is time consuming. Luckily, math is good at giving you ways to take shortcuts. To find an equation to represent this, if Pm represents the amount of money after m months, then we could write the recursive equation:

P0 = $1000

Pm = (1+0.0025)Pm-1

You probably recognize this as the recursive form of exponential growth. If not, we go through the steps to build an explicit equation for the growth in the next example.

Example

Build an explicit equation for the growth of $1000 deposited in a bank account offering 3% interest, compounded monthly.

View this video for a walkthrough of the concept of compound interest.

While this formula works fine, it is more common to use a formula that involves the number of years, rather than the number of compounding periods. If N is the number of years, then m = N k. Making this change gives us the standard formula for compound interest.

Compound Interest

[latex]P_{N}=P_{0}\left(1+\frac{r}{k}\right)^{Nk}[/latex]

  • PN is the balance in the account after N years.
  • P0 is the starting balance of the account (also called initial deposit, or principal)
  • r is the annual interest rate in decimal form
  • k is the number of compounding periods in one year
    • If the compounding is done annually (once a year), k = 1.
    • If the compounding is done quarterly, k = 4.
    • If the compounding is done monthly, k = 12.
    • If the compounding is done daily, k = 365.
The most important thing to remember about using this formula is that it assumes that we put money in the account once and let it sit there earning interest. 

In the next example, we show how to use the compound interest formula to find the balance on a certificate of deposit after 20 years.

Example

A certificate of deposit (CD) is a savings instrument that many banks offer. It usually gives a higher interest rate, but you cannot access your investment for a specified length of time. Suppose you deposit $3000 in a CD paying 6% interest, compounded monthly. How much will you have in the account after 20 years?

A video walkthrough of this example problem is available below.

Here is how you would enter it into the calculator (https://www.geogebra.org/m/XKxv7Xc2)

N = 20

I = 6

PV = 3000

FV = what you want to find (note that the answer is negative – PV and FV will always have opposite signs)

P/Y = 12

C/Y = 12

Let us compare the amount of money earned from compounding against the amount you would earn from simple interest

Years Simple Interest ($15 per month) 6% compounded monthly = 0.5% each month.
5 $3900 $4046.55
10 $4800 $5458.19
15 $5700 $7362.28
20 $6600 $9930.61
25 $7500 $13394.91
30 $8400 $18067.73
35 $9300 $24370.65

Line graph. Vertical axis: Account Balance ($), in increments of 5000 from 5000 to 25000. Horizontal axis: years, in increments of five, from 0 to 25. A blue dotted line shows a gradual increase over time, from roughly $2500 at year 0 to roughly $10000 at year 35. A pink dotted line shows a more dramatic increase, from roughly $2500 at year 0 to $25000 at year 35.

As you can see, over a long period of time, compounding makes a large difference in the account balance. You may recognize this as the difference between linear growth and exponential growth.

 

Evaluating exponents on the calculator

Here are some examples of how to solve compound interest problems using online time value of money calculators such as: Time Value of Money Solver

Example

You know that you will need $40,000 for your child’s education in 18 years. If your account earns 4% compounded quarterly, how much would you need to deposit now to reach your goal? Using the time value of money online calculator: https://www.geogebra.org/m/XKxv7Xc2

 

Rounding

It is important to be very careful about rounding when calculating things with exponents. In general, you want to keep as many decimals during calculations as you can. Be sure to keep at least 3 significant digits (numbers after any leading zeros). Rounding 0.00012345 to 0.000123 will usually give you a “close enough” answer, but keeping more digits is always better.

Example

To see why not over-rounding is so important, suppose you were investing $1000 at 5/12% interest compounded monthly for 30 years. Using an online time value of money calculator: https://www.geogebra.org/m/XKxv7Xc2

N=30 30 years
I% = 5/12 For the 5/12% interest rage
PV=1000 The $1,000 you are investing
P/Y and C/Y = 12 since we’re compounding monthly

When we compute the future value (the amount the $1,000 grows to, leaving PMT at zero because no payments are mentioned), we get $1,133.12

Here is the effect of rounding this to different values:

 5/12% rounded to: Gives FV to be: Error
0.4 $1,127.47 $259.15
0.42 $1,134.26 $53.71
0.417 $1,133.24 $5.35
0.4167 $1,133.14 $0.54
0.41667 $1,133.13 $0.06
no rounding $1,133.13

If you’re working in a bank, of course you wouldn’t round at all. For our purposes, the answer we got by rounding to five decimals, is close enough. Certainly keeping that fourth decimal place wouldn’t have hurt.

View the following for a demonstration of this example.

 

Using your calculator

In many cases, you can avoid rounding completely by how you enter things in your calculator. For example, in the example above, we needed to calculate [latex]{{P}_{30}}=1000{{\left(1+\frac{0.05}{12}\right)}^{12\times30}}[/latex]

We can quickly calculate 12×30 = 360, giving [latex]{{P}_{30}}=1000{{\left(1+\frac{0.05}{12}\right)}^{360}}[/latex].

Now we can use the calculator.

Type this Calculator shows
0.05 ÷ 12 = . 0.00416666666667
+ 1 = . 1.00416666666667
yx 360 = . 4.46774431400613
× 1000 = . 4467.74431400613

Using your calculator continued

The previous steps were assuming you have a “one operation at a time” calculator; a more advanced calculator will often allow you to type in the entire expression to be evaluated. If you have a calculator like this, you will probably just need to enter:

1000 ×  ( 1 + 0.05 ÷ 12 ) yx 360 =

Solving For Time

Note: This section assumes you’ve covered solving exponential equations using logarithms, either in prior classes or in the growth models chapter.

Often we are interested in how long it will take to accumulate money or how long we’d need to extend a loan to bring payments down to a reasonable level.

Examples

If you invest $2000 at 6% compounded monthly, how long will it take the account to double in value?

Get additional guidance for this example in the following: