Introduction
When calculating compound interest using  repeated applications of simple interest, we noticed that the total amount of an investment that uses compound interest increases at an increasing rate. While we can see this in how the interest amount increases year by year, it becomes a lot more obvious once we plot the investment's growth on a graph.
Compound and simple interest curves
When plotting compound interest, we want to see how the investment total changes over time. This means that our independent variable for the x-axis will be the number of periods that have passed and the dependent variable for the y-axis will be the investment total.
If we calculate what the investment total will be after some number of periods, we have both the x and y-values for a point that can be plotted.
Once we have plotted a few points, we can start to see how the curve joining the points for compound interest growth is non-linear. As expected, the curve will be increasing at an increasing rate.
If we compare the curve for a compound interest investment to a simple interest investment we can clearly see how compound interest results in a non-linear curve.
Examples
Example 1
Roxanne used repeated applications of simple interest to calculate how much an investment of \$200 would grow over 3 years if it earned compound interest at a rate of 22 \% p.a., compounding annually.
| \text{No. of years} | 0 | 1 | 2 | 3 |
|---|---|---|---|---|
| \text{Investment value (\$)} | 200 | 244 | 297.68 | 363.17 |
Which of the following graphs correctly shows the relationship between the number of years passed and the value of the investment?
Example 2
The graph below shows both an investment with simple interest, and one with compound interest, labelled Investment A and Investment B respectively.
Which investment has a higher principal amount?
Which investment has a higher final amount after 10 years?
After how many years are the investments equal in value?
Aspects of compound interest curves
When plotting a curve that represents compound interest growth, the different aspects of the compound interest scenario will be reflected in the different aspects of the graph.
A compound interest scenario has two key factors: the principal amount and the interest rate.
Since the principal amount is the amount invested at the start, it will always be the investment total after zero periods. In other words, the y-value of the y-intercept will always be the principal amount on a compound interest curve.
The interest rate will determine how steeply the curve increases. The greater the interest rate, the faster the investment will increase with respect to time. We can check whether an interest rate matches a graph by comparing two points that are one period apart. The increase from one y-value to the other should match the interest rate.
Examples
Example 3
Luke invests \$50 into an account which accumulates interest at a rate of 8 \, \% p.a., compounding annually.
Which of the following graphs correctly represents the relationship between the number of years passed and Luke's account balance?
How many years will it take for the account to reach a total value of \$200? Give your answer to the nearest whole number.
The y-value of the y-intercept will always be the principal amount on a compound interest curve.
The greater the interest rate, the faster the curve will increase with respect to time.