An annuity is a compound interest investment to which regular payments are made or from which regular payments are received for a fixed period of time. There are two types of annuities to consider: an investment account with regular, equal contributions and interest compounding at the end of each period, and a single-sum investment from which regular, equal withdrawals are made.
Making regular contributions
Here is an example where regular, equal deposits are made into an investment account and interest is compounded at the end of each period.
At the beginning of each year for $3$3 years, $\$500$$500 is deposited into an investment account that earns $3%$3% per annum interest.
- The first $\$500$$500 accrues interest for $3$3 years.
- The second $\$500$$500 accrues interest for $2$2 years.
- The third $\$500$$500 accrues interest for $1$1 year.
Notice that the funds in the account will increase quickly because of the regular contributions and the interest paid on the balance. We are interested in the total value of the investment after $3$3 years.
Since each equal, regular contribution earns compound interest, we can use the formula on each contribution separately to find the future value of the annuity as a whole.
From the example above:
- the first contribution will have a final value of $\$500\times1.03^3$$500×1.033
- the second will have a final value of $\$500\times1.03^2$$500×1.032
- the last contribution will have a final value of $\$500\times1.03$$500×1.03 by the end of the investment
However, for longer term investments, calculating the total in this way would be tedious. Take a close look at the series created by the investment $\$500\times1.03$$500×1.03 +$\$500\times1.03^2$$500×1.032 + $\$500\times1.03^3$$500×1.033. This is a geometric series. So, we can use the formula for the sum of a geometric sequence for these problems.
Worked example
Example 1
A bank client deposits $\$1000$$1000 at the beginning of each year, and is given $7%$7% interest per year for $50$50 years. How much will accrue in the account over that time?
Think: To develop a geometric sequence, let's consider the money that is in the account at the end of each year. Rather than calculating each amount, let's leave them in expanded form as this will allow us to see any patterns. If we set $A_n$An as the amount of money at the end of the $n$nth year, then we have:
$A_0=1000$A0=1000
And after one year, since $7%$7% interest has been added, we have:
| $A_1$A1 | $=$= | $1000\times\left(1.07\right)$1000×(1.07) |
By the end of the second year, another $\$1000$$1000 has been added and receives interest, but the original $\$1000$$1000 has been boosted by another interest payment too.
The total amount can be determined by:
| $A_2$A2 | $=$= | $(A_1+1000)(1.07)$(A1+1000)(1.07) |
| $A_2$A2 | $=$= | $1000\left(1.07\right)\left(1.07\right)+1000\left(1.07\right)$1000(1.07)(1.07)+1000(1.07) |
| $A_2$A2 | $=$= | $1000\left(1.07^2+1.07\right)$1000(1.072+1.07) |
By the end of the third year, the total accrual becomes:
$A_3=1000\left(1.07^3+1.07^2+1.07\right)$A3=1000(1.073+1.072+1.07)
Do: A pattern is emerging, and by the end of $50$50 years, the total accrued becomes:
$A_{50}=1000\left(1.07^{50}+1.07^{49}+1.07^{48}+...+1.07\right)$A50=1000(1.0750+1.0749+1.0748+...+1.07)
It might help to reverse the terms inside the brackets, so that we can see that we have is a geometric series with first term and common ratio both equal to $1.07$1.07:
$A_{50}=1000\left(1.07+1.07^2+1.07^3+...+1.07^{50}\right)$A50=1000(1.07+1.072+1.073+...+1.0750)
Hence, we can now state $a=1000$a=1000, $r=1.07$r=1.07, $n=50$n=50 and substitute into the formula $A_n=1000\times S_n$An=1000×Sn, where $S_n=\frac{a\left(r^n-1\right)}{r-1}$Sn=a(rn−1)r−1. So we have:
| $A_n$An | $=$= | $1000\left(\frac{a\left(r^n-1\right)}{r-1}\right)$1000(a(rn−1)r−1) |
| $A_n$An | $=$= | $1000\left(\frac{1.07\left(1.07^{50}-1\right)}{1.07-1}\right)$1000(1.07(1.0750−1)1.07−1) |
| $A_n$An | $\approx$≈ | $\$434985.95$$434985.95 |
Hence the amount accrued in the account will be approximately $\$434985.95$$434985.95.
We can use a different method to model the annuity, finding the final value of each investment at the end of the time period and adding them together. This will result in the same series as you find by calculating the value in the single investment account at the end of the total time period. Let's use this method in the example below, where the unknown is not the amount earned, but the size of each investment.
Example 2
Emily wishes to save $\$2000$$2000 throughout Year $11$11 and $12$12 for her schoolies trip. Beginning in January of Year $11$11, she deposits a certain amount into her bank account at the start of each month. Interest is paid at the end of each month, at a rate of $4%$4% p.a. compounding monthly. If she wishes to withdraw the $\$2000$$2000 at the end of November in Year $12$12, what is the size of each monthly deposit?
Think: before we develop our sequence, we need to find the values of $n$n and $r$r.
If she makes deposits from January until November of the following year, this means $n=23$n=23. $4%$4% p.a. becomes $\frac{4}{12}%$412% per month, so the $r$r for our geometric series will be:
$1+\frac{4}{1200}=1\frac{1}{300}$1+41200=11300
Do: In this example, we will let $A_n$An be the value of the $n$nth deposit at the end of November of Year $12$12. Let $M$M be the value of each monthly deposit.
Thus, $A_1=M\times(1\frac{1}{300})^{23}$A1=M×(11300)23, since the first deposit accrues interest over $23$23 months.
$A_2=M\times(1\frac{1}{300})^{22}$A2=M×(11300)22
$A_3=M\times(1\frac{1}{300})^{21}$A3=M×(11300)21
And so on, until we reach the last deposit:
$A_{23}=M\times(1\frac{1}{300})^1$A23=M×(11300)1
The sum of these $23$23 investments must equal $\$2000$$2000:
$2000=M\times(1\frac{1}{300})^1+M\times(1\frac{1}{300})^2+M\times(1\frac{1}{300})^3+\ldots+M\times(1\frac{1}{300})^{23}$2000=M×(11300)1+M×(11300)2+M×(11300)3+…+M×(11300)23
Factorising for $M$M, we can then add the geometric series inside the brackets with $a=1\frac{1}{300}$a=11300, $r=1\frac{1}{300}$r=11300 and $n=23$n=23:
$2000=M((1\frac{1}{300})^1+(1\frac{1}{300})^2+(1\frac{1}{300})^3+\ldots+(1\frac{1}{300})^{23})$2000=M((11300)1+(11300)2+(11300)3+…+(11300)23)
$2000=M\times1\frac{1}{300}(\frac{(1\frac{1}{300})^{23}-1}{1\frac{1}{300}-1})$2000=M×11300((11300)23−111300−1)
Rearranging to make $M$M the subject, we get:
$M=\$83.52$M=$83.52
Here are some tips and tricks that may help you in solving these problems:
- Remember, if the compounding period is not annual, you will need to divide the interest rate and multiply the number of time periods by the relevant value.
- The amount of interest earned is calculated by subtracting the sum of all contributed amounts from the final value of the investment.
Practice questions
Question 1
Which of the following are types of annuities?
An account in which you make regular contributions and the interest is paid at the end of each period.
AAn account in which you make contributions when you have spare money and the interest is paid at the beginning of each period.
BAn account from which you withdraw contributions that decrease as the balance decreases.
CAn account in which you make regular withdrawals and the interest is paid at the end of each period.
D
question 2
Maria invests $\$4000$$4000 at the end of each year for $4$4 years in an investment account that pays $5%$5% per annum with interest compounded monthly.
What value will her first deposit have grown to at the end of the $4$4 years?
What value will her second deposit have grown to at the end of the $4$4 years?
What value will her third deposit have grown to at the end of the $4$4 years?
What is the future value of the annuity correct to the nearest cent?
Question 3
At the start of 2014 Pauline deposits $\$5000$$5000 into an investment account. At the end of each quarter she makes an extra deposit of $\$700$$700. By looking at the pattern investment, Pauline realises she can use her knowledge of geometric series to find the balance in the account at some point in the future.
The table below shows the first few quarters of 2014. All values in the table are in dollars.
| Quarter | Opening Balance | Interest | Deposit | Closing Balance |
|---|---|---|---|---|
| Jan-Mar | $5000$5000 | $200$200 | $700$700 | $5900$5900 |
| Apr-Jun | $5900$5900 | $236.00$236.00 | $700$700 | $6836.00$6836.00 |
| Jul-Sep | $6836.00$6836.00 | $273.44$273.44 | $700$700 | $7809.44$7809.44 |
Use the numbers for the January quarter to calculate the quarterly interest rate.
Write an expression for the amount in the account at the end of the first quarter.
Do not evaluate the expression.
$\editable{}\times\editable{}+\editable{}$×+
Using $5000\times1.04+700$5000×1.04+700 as the starting balance, write an expression for the amount in the account at the end of the second quarter.
$\editable{}\times\left(\editable{}\right)^2+\editable{}\times\editable{}+\editable{}$×()2+×+
Given that the amount in the account at the end of the second quarter can be expressed as $5000\times\left(1.04\right)^2+700\times1.04+700$5000×(1.04)2+700×1.04+700, write a similar expression for the amount in the account at the end of the third quarter.
$\editable{}\times\left(\editable{}\right)^3+\editable{}\times\left(\editable{}\right)^2+\editable{}\times\editable{}+\editable{}$×()3+×()2+×+
The amount in the account after $n$n quarters can be expressed as a term of a geometric sequence plus the sum of a geometric sequence.
Write an expression for the amount in the investment account after $n$n quarters.
Hence determine the total amount in Pauline’s account at the beginning of 2016 to the nearest dollar.
Analysing our investment with a recurrence relation
Because of the pattern of regular and equal investments associated with an annuity, we can model them using a recurrence relation. To develop our first recursive model, let's look at the following scenario.
We'll invest $\$5000$$5000 at $6%$6% per annum interest compounded monthly. At the end of each month, after the interest has been applied, we'll make an additional deposit of $\$100$$100.
In order to develop a recursive model for this annuity, we first need to change our interest rate from annual to monthly by dividing by $12$12, so we get $0.5%$0.5% per month. At the end of each month, we increase the balance by $0.5%$0.5% ($\times1.005$×1.005) and then add $\$100$$100.
The balance at the end of the first few months may now be calculated as follows. (We are dealing with money, so we have rounded each balance to $2$2 decimal places and then use the rounded amount in the following row.)
| End of month 1 | $1.005\times5000+100$1.005×5000+100 | $=$= | $\$5125$$5125 |
| End of month 2 | $1.005\times5125+100$1.005×5125+100 | $=$= | $\$5250.63$$5250.63 |
| End of month 3 | $1.005\times5250.63+100$1.005×5250.63+100 | $=$= | $\$5376.88$$5376.88 |
Notice a recurring pattern:
$\text{Balance at the end of the month }=\text{Balance at the beginning }\times1.005+100$Balance at the end of the month =Balance at the beginning ×1.005+100
The balance at the end of each month is carried forward to be the starting balance in the account. Hence, using the notation we previously encountered using recurrence relations, we can write this as:
$A_n=A_{n-1}\times1.005+100$An=An−1×1.005+100, $A_0=5000$A0=5000.
To examine the balance in a few years time, we don't want to manually calculate the values in the table. We could use a spreadsheet, or use the formula for the sum of a geometric sequence as demonstrated previously.
Practice questions
Question 4
Nadia initially deposits $\$7000$$7000 into an investment account. At the end of each quarter, Nadia makes an extra deposit of $\$500$$500.
The table below shows the first few quarters of 2015. All values in the table are in dollars.
| Month | Balance at beginning of quarter | Interest | Deposit | Balance at end of quarter |
|---|---|---|---|---|
| Jan-Mar | $7000$7000 | $140$140 | $500$500 | $7640$7640 |
| Apr-Jun | $7640$7640 | $152.80$152.80 | $500$500 | $8292.80$8292.80 |
| Jul-Sep | $8292.80$8292.80 | $165.86$165.86 | $500$500 | $8958.66$8958.66 |
Use the numbers for the January quarter to calculate the quarterly interest rate.
Calculate the annual interest rate of her investment.
Fill in the row for the October quarter. Give all values to the nearest cent.
Month Balance at beginning of quarter Interest Deposit Balance at end of quarter Jan-Mar $7000$7000 $140$140 $500$500 $7640$7640 Apr-Jun $7640$7640 $152.80$152.80 $500$500 $8292.80$8292.80 Jul-Sep $8292.80$8292.80 $165.86$165.86 $500$500 $8958.66$8958.66 Oct-Dec $\editable{}$ $\editable{}$ $\editable{}$ $\editable{}$
Question 5
The spreadsheet below shows the first year of an investment with regular deposits.
| $A$A | $B$B | $C$C | $D$D | $E$E | |
| $1$1 | Year | Beginning Balance | Interest | Deposit | End Balance |
| $2$2 | $1$1 | $6000$6000 | $660$660 | $500$500 | $7160$7160 |
| $3$3 | |||||
| $4$4 | |||||
| $5$5 |
Calculate the annual interest rate for this investment.
Write a formula for cell $B$B$3$3.
Enter only one letter or number per box.
$B$B$3$3 $=$= $\editable{}$$\editable{}$
Write a formula for cell $C$C$6$6 in terms of $B$B$6$6.
Enter one letter or a number per box.
$C$C$6$6 $=$= $\editable{}$$\ast$∗$\editable{}$$\editable{}$
Which of the following is the correct formula for cell $E$E$5$5?
$B$B $5$5 $\ast$∗ $C$C $5$5 $+$+ $D$D $5$5
A$B$B $5$5 $+$+ $C$C $5$5 $-$− $D$D $5$5
B$B$B $5$5 $+$+ $C$C $5$5 $+$+ $D$D $5$5
C$B$B $5$5 $+$+ $C$C $5$5 $\ast$∗ $D$D $5$5
D$B$B $5$5 $\ast$∗ $C$C $5$5 $\ast$∗ $D$D $5$5
E$B$B $5$5 $-$− $C$C $5$5 $-$− $D$D $5$5
FUse technology to reproduce this spreadsheet and determine the end balance for the $4$4th year.
Calculate the total interest earned over these $4$4 years.