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6. Loans, Investments, & Annuities
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AustraliaAU
Year 12

6.06 Perpetuities

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Lesson

Perpetuity

A perpetuity is a type of investment in which regular withdrawals are made. However, the balance remains stable as the withdrawal amount exactly equals the interest accrued for each time period. A good way to remember this is to think of a 'perpetual trophy' which is a trophy that continues to be awarded each year. A perpetuity fund continues forever.

The equation for perpetuity is: \text{Withdrawal amount (payment)} = \text{Interest accrued} or Q = A \times r where Q is the amount of interest earned (size of the prize or payment), A is the initial amount invested in dollars, and r is the interest rate for the period as a decimal.

Examples

Example 1

Farzad invests his workers' compensation payout of \$2\,760\,000 in a perpetuity that pays 2.85\% per annum, compounding quarterly. What is the size of the quarterly payment he will receive?

Worked Solution
Create a strategy

Use the perpetuity equation.

Apply the idea

We are asked to solve for Q per quarter but we are given an annual interest rate. So we will divide r by 4 to convert it to a quarterly interest rate.

So A=2\,760\,000 and r=\dfrac{2.85\%}{4}=\dfrac{0.0285}{4}.

\displaystyle Q\displaystyle =\displaystyle A\times rUse the perpetuity equation
\displaystyle =\displaystyle 2\,760\,000 \times \dfrac{0.0285}{4}Substitute A and r
\displaystyle =\displaystyle \$19\,665.00Evaluate
Idea summary

The perpetuity equation:

\displaystyle Q = A \times r
\bm{Q}
is the amount of interest earned (size of the payment)
\bm{A}
is the initial amount invested
\bm{r}
is the interest rate for the period as a decimal

Perpetuities with the financial application

We can solve problems involving perpetuities using a financial application by setting the present value (PV) and future value (FV) equal to the same amount. However, the present value should be entered as a negative to indicate depositing the money for investment. The payment (PMT) in this case will be positive as this is returned to the investor.

Examples

Example 2

Hermione invests her superannuation payout of \$500\,000 into a perpetuity that will provide a monthly income without using any of the initial investment. If the interest rate of the perpetuity is 9\% per annum compounded annually, what monthly payment will Hermione receive?

a

Fill in the values for each of the following. Put an X next to the variable we wish to solve for.

N1
I\%⬚\%
PV
PMT
FV
P/Y
C/Y
Worked Solution
Create a strategy

Use the given information to find each value, keeping in mind that the PV and PMT should be opposite in sign to FV.

Apply the idea

I(\%) is the annual interest rate which is 9\%.

PV is the present value of her investment which is initially \$500\,000. Since she is giving this money to the bank, she no longer has it, so we can think of it as she is losing it. So we should make it negative: -\$500\,000.

PMT is the regular monthly payment which we are solving for.

FV is the future value of the investment which should be the positive version of the PV which is \$500\,000.

P/Y is the number of payments per year which is 12 since she received monthly payments.

C/Y is the number of compounding periods each year which is 1 since the interest is compounded annually.

N1
I\%9\%
PV-500\,000
PMTX
FV500\,000
P/Y12
C/Y1
b

Hence determine the monthly payment in dollars.

Worked Solution
Create a strategy

Using technology, enter the values from part (a) into a financial solver function, and solve for the monthly payment PMT.

Apply the idea

Using your calculator and pressing Enter in the PMT box you should get PMT=3750.

So the monthly payment is \$3750.

Idea summary

When solving problems involving perpetuities using a financial application, the present value (PV) and future value (FV) equal the same amount, but the present value should be entered as a negative. The payment (PMT) should be entered as a positive.

Perpetuities as recurrence relations

This is similar to modelling an  investment with regular payments  with the payment in this case being withdrawn and hence, negative in the form shown below. A perpetuity is a special case of such an investment where the balance stays constant.

For a principal investment, P, at the compound interest rate of r per period and a payment d withdrawn per period, the sequence of the value of the investment over time forms a first order linear recurrence.

The sequence which generates the value, V_{n}, of the investment at the end of each instalment period is:

  • Recursive sequence: V_{n}=V_{n-1} \times \left(1+r \right) - d, where V_{0}=P

The sequence which generates the value, V_{n}, of the investment at the beginning of each instalment period is:

  • Recursive sequence: V_{n}=V_{n-1} \times \left(1+r \right) - d, where V_{1}=P

If the situation is a perpetuity we will have:

  • A constant term sequence with each term being the initial investment.

  • The payment, d, will be equal to the initial investment multiplied by the rate per period. That is, the payment is the interest accrued each period.

Examples

Example 3

\$16\,000 is invested in a perpetuity at 3\% per annum, compounded annually. A constant amount is withdrawn from the account at the end of each year.

This perpetuity can be defined recursively by A_{n+1} = aA_{n}-b, A_{0}=c, where A_{n+1} is the amount remaining in the account after n+1 years.

State the values of a, \, b, and c.

Worked Solution
Create a strategy

Use the recursive sequence: V_{n}=V_{n-1} \times \left(1+r \right) - d, where V_{0}=P

Apply the idea

By comparing the given rule and the above recursive sequence form, we can see that a=1+r, \, b=d, and c=P.

But d is equal to the initial investment multiplied by the rate per period, so b=d=P\times r.

\displaystyle a\displaystyle =\displaystyle 1+3\%Substitute r=3\%
\displaystyle =\displaystyle 1+0.03Write as a decimal
\displaystyle =\displaystyle 1.03Simplify
\displaystyle c\displaystyle =\displaystyle 16\,000Substitute the initial investment
\displaystyle b\displaystyle =\displaystyle 16\,000 \times 0.03Substitute P and r
\displaystyle =\displaystyle 460Evaluate

So a=1.03, \, b=480, and c=16\,000.

Idea summary

For a principal investment, P, at the compound interest rate of r per period and a payment d withdrawn per period, the sequence of the value of the investment over time forms a first order linear recurrence.

The sequence which generates the value, V_{n}, of the investment at the end of each instalment period is:

  • Recursive sequence: V_{n}=V_{n-1} \times \left(1+r \right) - d, where V_{0}=P

The sequence which generates the value, V_{n}, of the investment at the beginning of each instalment period is:

  • Recursive sequence: V_{n}=V_{n-1} \times \left(1+r \right) - d, where V_{1}=P

Where d is equal to the initial investment multiplied by the rate per period.

Outcomes

ACMGM100

with the aid of a financial calculator or computer-based financial software, solve problems involving annuities (including perpetuities as a special case); for example, determining the amount to be invested in an annuity to provide a regular monthly income of a certain amount

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