The table below compares the effect of changing the number of compounding periods when $\$1000$$1000 is invested for one year at a nominal rate of $5%$5% p.a. The final amount is calculated using the compound interest formula $A=P\times(1+\frac{r}{n})^{nt}$A=P×(1+rn)nt
|
Number of compounding periods |
$1$1 |
$4$4 |
$365$365 |
|---|---|---|---|
| Calculation | $A=1000\times(1+\frac{0.05}{1})^1$A=1000×(1+0.051)1 $=1000\times(1.05)$=1000×(1.05) |
$A=1000\times(1+\frac{0.05}{4})^4$A=1000×(1+0.054)4 $=1000\times(1.05095)$=1000×(1.05095) |
$A=1000\times(1+\frac{0.05}{365})^{365}$A=1000×(1+0.05365)365 $=1000\times(1.05127)$=1000×(1.05127) |
| Final amount | $\$1050$$1050 | $\$1050.95$$1050.95 | $\$1051.27$$1051.27 |
| Amount of interest | $\$50$$50 | $\$50.95$$50.95 | $\$51.27$$51.27 |
| Effective annual interest rate | $\frac{50}{1000}=0.05=5%$501000=0.05=5% | $\frac{50.95}{1000}=0.05095=5.095%$50.951000=0.05095=5.095% | $\frac{51.27}{1000}=0.05127=5.127%$51.271000=0.05127=5.127% |
From the table we can see that the amount of interest earned increases when the number of compounding periods increases.
The effective annual interest rate has been calculated using the formula:
$\text{effective interest rate}=\frac{\text{Interest earned in one year}}{\text{Balance at start of year }}\times100%$effective interest rate=Interest earned in one yearBalance at start of year ×100%
The published rate of $5%$5% per annum is called the nominal interest rate.
Note: If we only compound once per year then this nominal interest rate is the same as the effective interest rate.
$i_{effective}=(1+\frac{i}{n})^n-1$ieffective=(1+in)n−1
where $i_{effective}$ieffective is the effective interest rate per annum, expressed as a decimal
$i$i is the nominal (or published) interest rate per annum, expressed as a decimal
$n$n is the number of compounding periods per annum
Being able to calculate the effective interest rate can come in handy when we are choosing and comparing investments or loans. They allow us to more easily work out how much interest the investment or loan will actually earn and quickly compare rates that have different compounding periods.
When investing money, we want to have the highest possible effective interest rate.
When borrowing money, we want to have the lowest possible effective interest rate.
Worked examples
example 1
A bank advertises a nominal interest rate of $5.6%$5.6% per annum, compounded quarterly. Calculate the effective interest rate.
Think: Using the effective interest rate formula, we are solving for $i_{effective}$ieffective where $i=0.056$i=0.056 and $n=4$n=4.
Do:
| $i_{effective}$ieffective | $=$= | $\left(1+\frac{i}{n}\right)^n-1$(1+in)n−1 |
|
| $=$= | $(1+\frac{0.056}{4})^4-1$(1+0.0564)4−1 |
|
|
| $\approx$≈ | $1.057187-1$1.057187−1 |
Evaluate using a calculator |
|
| $=$= | $0.0572$0.0572 to $3$3 significant figures |
|
Therefore, the effective interest rate is $5.72%$5.72% p.a. to $2$2 decimal places.
Another option is to use the interest rate conversion facility in the financial application of your calculator. See below for instructions on how to do this. Remember: If you use the app you must make sure to write down the numbers you put in your calculator as your working.
example 2
The effective rate for an investment account which compounds monthly is $6.4%$6.4% p.a.. Calculate the nominal rate for this account correct to two decimal places.
Think: Using the effective interest rate formula, we want to solve for $i$i, where $n=12$n=12 and $i_{effective}=0.064$ieffective=0.064.
Do:
| $i_{effective}$ieffective | $=$= | $(1+\frac{i}{n})^n-1$(1+in)n−1 |
|
| $0.064$0.064 | $=$= | $(1+\frac{i}{12})^{12}-1$(1+i12)12−1 |
Using the solve facility of our calculator. |
| $i$i | $=$= | $0.0622$0.0622 to $3$3 significant figures |
|
Therefore, the nominal rate of interest is $6.22%$6.22% p.a. to two decimal places.
Alternatively, use interest rate conversion facility in the financial application of your calculator.
Using technology to find effective rates
Select the brand of calculator you use below to work through an example of using a calculator to find effective rates.
Casio Classpad
How to use the CASIO Classpad to find effective interest rates for compound interest investments or loans.
Consider the following loan options:
Option A: 5.70% p.a. compounded quarterly
Option B: 5.65% p.a. compounded monthly
What is the effective rate of option A correct to two decimal places?
What is the effective rate of option B correct to two decimal places?
Which option offers a better rate?
TI Nspire
How to use the TI Nspire to find effective interest rates for compound interest investments or loans.
Consider the following loan options:
Option A: 5.70% p.a. compounded quarterly
Option B: 5.65% p.a. compounded monthly
What is the effective rate of option A correct to two decimal places?
What is the effective rate of option B correct to two decimal places?
Which option offers a better rate?
Practice questions
Question 1
James invested $\$3000$$3000 at $4.6%$4.6% p.a. compounded daily.
Find the amount of interest earned in a year. You may assume that there are $365$365 days in a year (ignoring leap years).
Write your answer to the nearest cent.
Find the effective annual interest rate as a percentage to two decimal places.
Question 2
An investment earns interest at a rate of $7.2%$7.2% compounding semiannually.
What is the effective rate correct to two decimal places?