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# Finance

## Introduction

Should you ever find yourself stuck with a mathematics question on a television quiz show, you will probably wish you had remembered how many even prime numbers there are between 1 and 100 for the sake of R1 000 000. And who does not want to be a millionaire, right?

Welcome to the Grade 10 Finance Chapter, where we apply maths skills to everyday financial situations that you are likely to face both now and along your journey to purchasing your first private jet.

If you master the techniques in this chapter, you will grasp the concept of compound interest, and how it can ruin your fortunes if you have credit card debt, or make you millions if you successfully invest your hard-earned money. You will also understand the effects of fluctuating exchange rates, and its impact on your spending power during your overseas holidays!

Before we begin this chapter it is worth noting that the vast majority of countries use a decimal currency system. This simply means that countries use a currency system that works with powers of ten, for example in South Africa we have 100 (10 squared) cents in a rand. In America there are 100 cents in a dollar. Another way of saying this is that the country has one basic unit of currency and a sub-unit which is a power of 10 of the major unit. This means that, if we ignore the effect of exchange rates, we can essentially substitute rands for dollars or rands for pounds.

## Being Interested in Interest

If you had R1 000, you could either keep it in your wallet, or deposit it in a bank account. If it stayed in your wallet, you could spend it any time you wanted. If the bank looked after it for you, then they could spend it, with the plan of making profit from it. The bank usually “pays" you to deposit it into an account, as a way of encouraging you to bank it with them, This payment is like a reward, which provides you with a reason to leave it with the bank for a while, rather than keeping the money in your wallet.

We call this reward "interest".

If you deposit money into a bank account, you are effectively lending money to the bank - and you can expect to receive interest in return. Similarly, if you borrow money from a bank (or from a department store, or a car dealership, for example) then you can expect to have to pay interest on the loan. That is the price of borrowing money.

The concept is simple, yet it is core to the world of finance. Accountants, actuaries and bankers, for example, could spend their entire working career dealing with the effects of interest on financial matters.

In this chapter you will be introduced to the concept of financial mathematics - and given the tools to cope with even advanced concepts and problems.

### Tip:

Interest

The concepts in this chapter are simple - we are just looking at the same idea, but from many different angles. The best way to learn from this chapter is to do the examples yourself, as you work your way through. Do not just take our word for it!

## Simple Interest

Definition 1: Simple Interest

Simple interest is where you earn interest on the initial amount that you invested, but not interest on interest.

As an easy example of simple interest, consider how much you will get by investing R1 000 for 1 year with a bank that pays you 5% simple interest. At the end of the year, you will get an interest of:

Interest = R 1 000 × 5 % = R 1 000 × 5 100 = R 1 000 × 0 , 05 = R 50 Interest = R 1 000 × 5 % = R 1 000 × 5 100 = R 1 000 × 0 , 05 = R 50
(1)

So, with an “opening balance" of R1 000 at the start of the year, your “closing balance" at the end of the year will therefore be:

Closing Balance = Opening Balance + Interest = R 1 000 + R 50 = R 1 050 Closing Balance = Opening Balance + Interest = R 1 000 + R 50 = R 1 050
(2)

We sometimes call the opening balance in financial calculations the Principal, which is abbreviated as PP (R1 000 in the example). The interest rate is usually labelled ii (5% in the example), and the interest amount (in Rand terms) is labelled II (R50 in the example).

So we can see that:

I = P × i I = P × i
(3)

and

Closing Balance = Opening Balance + Interest = P + I = P + ( P × i ) = P ( 1 + i ) Closing Balance = Opening Balance + Interest = P + I = P + ( P × i ) = P ( 1 + i )
(4)

This is how you calculate simple interest. It is not a complicated formula, which is just as well because you are going to see a lot of it!

### Not Just One

You might be wondering to yourself:

1. how much interest will you be paid if you only leave the money in the account for 3 months, or
2. what if you leave it there for 3 years?

It is actually quite simple - which is why they call it Simple Interest.

1. Three months is 1/4 of a year, so you would only get 1/4 of a full year's interest, which is: 1/4×(P×i)1/4×(P×i). The closing balance would therefore be:
Closing Balance =P+1/4×(P×i)=P(1+(1/4)i) Closing Balance =P+1/4×(P×i)=P(1+(1/4)i)
(5)
2. For 3 years, you would get three years' worth of interest, being: 3×(P×i)3×(P×i). The closing balance at the end of the three year period would be:
Closing Balance =P+3×(P×i)=P×(1+(3)i) Closing Balance =P+3×(P×i)=P×(1+(3)i)
(6)

If you look carefully at the similarities between the two answers above, we can generalise the result. If you invest your money (PP) in an account which pays a rate of interest (ii) for a period of time (nn years), then, using the symbol AA for the Closing Balance:

A = P ( 1 + i · n ) A = P ( 1 + i · n )
(7)

As we have seen, this works when nn is a fraction of a year and also when nn covers several years.

#### Important: Interest Calculation:

Annual Rates means Yearly rates. and p.a.(per annum) = per year

#### Exercise 1: Simple Interest

If I deposit R1 000 into a special bank account which pays a Simple Interest of 7% for 3 years, how much will I get back at the end of this term?

##### Solution
1. Step 1. Determine what is given and what is required :
• opening balance, P=R1000P=R1000
• interest rate, i=7%i=7%
• period of time, n=3 years n=3 years

We are required to find the closing balance (A).

2. Step 2. Determine how to approach the problem :

We know from Equation 7 that:

A = P ( 1 + i · n ) A = P ( 1 + i · n )
(8)
3. Step 3. Solve the problem :
A = P ( 1 + i · n ) = R 1 000 ( 1 + 3 × 7 % ) = R 1 210 A = P ( 1 + i · n ) = R 1 000 ( 1 + 3 × 7 % ) = R 1 210
(9)
4. Step 4. Write the final answer :

The closing balance after 3 years of saving R1 000 at an interest rate of 7% is R1 210.

#### Exercise 2: Calculating nn

If I deposit R30 000 into a special bank account which pays a Simple Interest of 7.5%, for how many years must I invest this amount to generate R45 000?

##### Solution
1. Step 1. Determine what is given and what is required :
• opening balance, P=R30000P=R30000
• interest rate, i=7,5%i=7,5%
• closing balance, A=R45000A=R45000

We are required to find the number of years.

2. Step 2. Determine how to approach the problem :

We know from Equation 7 that:

A = P ( 1 + i · n ) A = P ( 1 + i · n )
(10)
3. Step 3. Solve the problem :
A = P ( 1 + i · n ) R 45 000 = R 30 000 ( 1 + n × 7 , 5 % ) ( 1 + 0 , 075 × n ) = 45000 30000 0 , 075 × n = 1 , 5 - 1 n = 0 , 5 0 , 075 n = 6 , 6666667 n = 6 years 8 months A = P ( 1 + i · n ) R 45 000 = R 30 000 ( 1 + n × 7 , 5 % ) ( 1 + 0 , 075 × n ) = 45000 30000 0 , 075 × n = 1 , 5 - 1 n = 0 , 5 0 , 075 n = 6 , 6666667 n = 6 years 8 months
(11)
4. Step 4. Write the final answer :

The period is 6 years and 8 months for R30 000 to generate R45 000 at a simple interest rate of 7,5%. If we were asked for the nearest whole number of years, we would have to invest the money for 7 years.

### Other Applications of the Simple Interest Formula

#### Exercise 3: Hire-Purchase

Troy is keen to buy an additional hard drive for his laptop advertised for R 2 500 on the internet. There is an option of paying a 10% deposit then making 24 monthly payments using a hire-purchase agreement where interest is calculated at 7,5% p.a. simple interest. Calculate what Troy's monthly payments will be.

##### Solution
1. Step 1. Determine what is given and what is required :

A new opening balance is required, as the 10% deposit is paid in cash.

• 10% of R 2 500 = R250
• new opening balance, P=R2500-R250=R2250P=R2500-R250=R2250
• interest rate, i=7,5%i=7,5%
• period of time, n=2 years n=2 years

We are required to find the closing balance (A) and then the monthly payments.

2. Step 2. Determine how to approach the problem :

We know from Equation 7 that:

A = P ( 1 + i · n ) A = P ( 1 + i · n )
(12)
3. Step 3. Solve the problem :
A = P ( 1 + i · n ) = R 2 250 ( 1 + ( 2 × 7 , 5 % ) ) = R 2 587 , 50 Monthly payment = 2587 , 50 ÷ 24 = R 107 , 81 A = P ( 1 + i · n ) = R 2 250 ( 1 + ( 2 × 7 , 5 % ) ) = R 2 587 , 50 Monthly payment = 2587 , 50 ÷ 24 = R 107 , 81
(13)
4. Step 4. Write the final answer :

Troy's monthly payments = R 107,81

Many items become less valuable as they are used and age. For example, you pay less for a second hand car than a new car of the same model. The older a car is the less you pay for it. The reduction in value with time can be due purely to wear and tear from usage but also to the development of new technology that makes the item obsolete, for example, new computers that are released force down the value of older models. The term we use to descrive the decrease in value of items with time is depreciation.

Depreciation, like interest can be calculated on an annual basis and is often done with a rate or percentage change per year. It is like ”negative” interest. The simplest way to do depreciation is to assume a constant rate per year, which we will call simple depreciation. There are more complicated models for depreciation but we won't deal with them here.

#### Exercise 4: Depreciation

Seven years ago, Tjad's drum kit cost him R12 500. It has now been valued at R2 300. What rate of simple depreciation does this represent ?

##### Solution
1. Step 1. Determine what is given and what is required :
• opening balance, P=R12500P=R12500
• period of time, n=7 years n=7 years
• closing balance, A=R2300A=R2300

We are required to find the interest rate(ii).

2. Step 2. Determine how to approach the problem :

We know from Equation 7 that:

A = P ( 1 + i · n ) A = P ( 1 + i · n )
(14)

Therefore, for depreciation the formula will change to:

A = P ( 1 - i · n ) A = P ( 1 - i · n )
(15)
3. Step 3. Solve the problem :
A = P ( 1 - i · n ) R 2 300 = R 12 500 ( 1 - 7 × i ) i = 0 , 11657 . . . A = P ( 1 - i · n ) R 2 300 = R 12 500 ( 1 - 7 × i ) i = 0 , 11657 . . .
(16)
4. Step 4. Write the final answer :

Therefore the rate of depreciation is 11,66%11,66%

#### Simple Interest

1. An amount of R3 500 is invested in a savings account which pays simple interest at a rate of 7,5% per annum. Calculate the balance accumulated by the end of 2 years.
2. Calculate the simple interest for the following problems.
1. A loan of R300 at a rate of 8% for l year.
2. An investment of R225 at a rate of 12,5% for 6 years.
3. I made a deposit of R5 000 in the bank for my 5 year old son's 21st birthday. I have given him the amount of R 18 000 on his birthday. At what rate was the money invested, if simple interest was calculated ?
4. Bongani buys a dining room table costing R 8 500 on Hire Purchase. He is charged simple interest at 17,5% per annum over 3 years.
1. How much will Bongani pay in total ?
2. How much interest does he pay ?
3. What is his monthly installment ?

## Compound Interest

To explain the concept of compound interest, the following example is discussed:

### Exercise 5: Using Simple Interest to lead to the concept Compound Interest

I deposit R1 000 into a special bank account which pays a Simple Interest of 7%. What if I empty the bank account after a year, and then take the principal and the interest and invest it back into the same account again. Then I take it all out at the end of the second year, and then put it all back in again? And then I take it all out at the end of 3 years?

#### Solution

1. Step 1. Determine what is given and what is required :
• opening balance, P=R1000P=R1000
• interest rate, i=7%i=7%
• period of time, 1 year 1 year at a time, for 3 years

We are required to find the closing balance at the end of three years.

2. Step 2. Determine how to approach the problem :

We know that:

A = P ( 1 + i · n ) A = P ( 1 + i · n )
(17)
3. Step 3. Determine the closing balance at the end of the first year :
A = P ( 1 + i · n ) = R 1 000 ( 1 + 1 × 7 % ) = R 1 070 A = P ( 1 + i · n ) = R 1 000 ( 1 + 1 × 7 % ) = R 1 070
(18)
4. Step 4. Determine the closing balance at the end of the second year :

After the first year, we withdraw all the money and re-deposit it. The opening balance for the second year is therefore R1070R1070, because this is the balance after the first year.

A = P ( 1 + i · n ) = R 1 070 ( 1 + 1 × 7 % ) = R 1 144 , 90 A = P ( 1 + i · n ) = R 1 070 ( 1 + 1 × 7 % ) = R 1 144 , 90
(19)
5. Step 5. Determine the closing balance at the end of the third year :

After the second year, we withdraw all the money and re-deposit it. The opening balance for the third year is therefore R1144,90R1144,90, because this is the balance after the first year.

A = P ( 1 + i · n ) = R 1 144 , 90 ( 1 + 1 × 7 % ) = R 1 225 , 04 A = P ( 1 + i · n ) = R 1 144 , 90 ( 1 + 1 × 7 % ) = R 1 225 , 04
(20)
6. Step 6. Write the final answer :

The closing balance after withdrawing all the money and re-depositing each year for 3 years of saving R1 000 at an interest rate of 7% is R1 225,04.

In the two worked examples using simple interest (Exercise 1 and Exercise 5), we have basically the same problem because PP=R1 000, ii=7% and nn=3 years for both problems. Except in the second situation, we end up with R1 225,04 which is more than R1 210 from the first example. What has changed?

In the first example I earned R70 interest each year - the same in the first, second and third year. But in the second situation, when I took the money out and then re-invested it, I was actually earning interest in the second year on my interest (R70) from the first year. (And interest on the interest on my interest in the third year!)

This more realistically reflects what happens in the real world, and is known as Compound Interest. It is this concept which underlies just about everything we do - so we will look at it more closely next.

Definition 2: Compound Interest

Compound interest is the interest payable on the principal and its accumulated interest.

Compound interest is a double-edged sword, though - great if you are earning interest on cash you have invested, but more serious if you are stuck having to pay interest on money you have borrowed!

In the same way that we developed a formula for Simple Interest, let us find one for Compound Interest.

If our opening balance is PP and we have an interest rate of ii then, the closing balance at the end of the first year is:

Closing Balance after 1 year = P ( 1 + i ) Closing Balance after 1 year = P ( 1 + i )
(21)

This is the same as Simple Interest because it only covers a single year. Then, if we take that out and re-invest it for another year - just as you saw us doing in the worked example above - then the balance after the second year will be:

Closing Balance after 2 years = [ P ( 1 + i ) ] × ( 1 + i ) = P ( 1 + i ) 2 Closing Balance after 2 years = [ P ( 1 + i ) ] × ( 1 + i ) = P ( 1 + i ) 2
(22)

And if we take that money out, then invest it for another year, the balance becomes:

Closing Balance after 3 years = [ P ( 1 + i ) 2 ] × ( 1 + i ) = P ( 1 + i ) 3 Closing Balance after 3 years = [ P ( 1 + i ) 2 ] × ( 1 + i ) = P ( 1 + i ) 3
(23)

We can see that the power of the term (1+i)(1+i) is the same as the number of years. Therefore,

Closing Balance after n years = P ( 1 + i ) n Closing Balance after n years = P ( 1 + i ) n
(24)

### Fractions add up to the Whole

It is easy to show that this formula works even when nn is a fraction of a year. For example, let us invest the money for 1 month, then for 4 months, then for 7 months.

Closing Balance after 1 month = P ( 1 + i ) 1 12 Closing Balance after 5 months = Closing Balance after 1 month invested for 4 months more = [ P ( 1 + i ) 1 12 ] ( 1 + i ) 4 12 = P ( 1 + i ) 1 12 + 4 12 = P ( 1 + i ) 5 12 Closing Balance after 12 months = Closing Balance after 5 months invested for 7 months more = [ P ( 1 + i ) 5 12 ] ( 1 + i ) 7 12 = P ( 1 + i ) 5 12 + 7 12 = P ( 1 + i ) 12 12 = P ( 1 + i ) 1 Closing Balance after 1 month = P ( 1 + i ) 1 12 Closing Balance after 5 months = Closing Balance after 1 month invested for 4 months more = [ P ( 1 + i ) 1 12 ] ( 1 + i ) 4 12 = P ( 1 + i ) 1 12 + 4 12 = P ( 1 + i ) 5 12 Closing Balance after 12 months = Closing Balance after 5 months invested for 7 months more = [ P ( 1 + i ) 5 12 ] ( 1 + i ) 7 12 = P ( 1 + i ) 5 12 + 7 12 = P ( 1 + i ) 12 12 = P ( 1 + i ) 1
(25)

which is the same as investing the money for a year.

Look carefully at the long equation above. It is not as complicated as it looks! All we are doing is taking the opening amount (PP), then adding interest for just 1 month. Then we are taking that new balance and adding interest for a further 4 months, and then finally we are taking the new balance after a total of 5 months, and adding interest for 7 more months. Take a look again, and check how easy it really is.

Does the final formula look familiar? Correct - it is the same result as you would get for simply investing PP for one full year. This is exactly what we would expect, because:

1 month + 4 months + 7 months = 12 months, which is a year.

Can you see that? Do not move on until you have understood this point.

### The Power of Compound Interest

To see how important this “interest on interest" is, we shall compare the difference in closing balances for money earning simple interest and money earning compound interest. Consider an amount of R10 000 that you have to invest for 10 years, and assume we can earn interest of 9%. How much would that be worth after 10 years?

The closing balance for the money earning simple interest is:

A = P ( 1 + i · n ) = R 10 000 ( 1 + 9 % × 10 ) = R 19 000 A = P ( 1 + i · n ) = R 10 000 ( 1 + 9 % × 10 ) = R 19 000
(26)

The closing balance for the money earning compound interest is:

A = P ( 1 + i ) n = R 10 000 ( 1 + 9 % ) 10 = R 23 673 , 64 A = P ( 1 + i ) n = R 10 000 ( 1 + 9 % ) 10 = R 23 673 , 64
(27)

So next time someone talks about the “magic of compound interest", not only will you know what they mean - but you will be able to prove it mathematically yourself!

Again, keep in mind that this is good news and bad news. When you are earning interest on money you have invested, compound interest helps that amount to increase exponentially. But if you have borrowed money, the build up of the amount you owe will grow exponentially too.

#### Exercise 6: Taking out a Loan

Mr Lowe wants to take out a loan of R 350 000. He does not want to pay back more than R625 000 altogether on the loan. If the interest rate he is offered is 13%, over what period should he take the loan.

##### Solution
1. Step 1. Determine what has been provided and what is required :
• opening balance, P=R350000P=R350000
• closing balance, A=R625000A=R625000
• interest rate, i=13% per year i=13% per year

We are required to find the time period(nn).

2. Step 2. Determine how to approach the problem :

We know from Equation 24 that:

A = P ( 1 + i ) n A = P ( 1 + i ) n
(28)

We need to find nn.

Therefore we convert the formula to:

A P = ( 1 + i ) n A P = ( 1 + i ) n
(29)

and then find nn by trial and error.

3. Step 3. Solve the problem :
A P = ( 1 + i ) n 625000 350000 = ( 1 + 0 , 13 ) n 1 , 785 . . . = ( 1 , 13 ) n Try n = 3 : ( 1 , 13 ) 3 = 1 , 44 . . . Try n = 4 : ( 1 , 13 ) 4 = 1 , 63 . . . Try n = 5 : ( 1 , 13 ) 5 = 1 , 84 . . . A P = ( 1 + i ) n 625000 350000 = ( 1 + 0 , 13 ) n 1 , 785 . . . = ( 1 , 13 ) n Try n = 3 : ( 1 , 13 ) 3 = 1 , 44 . . . Try n = 4 : ( 1 , 13 ) 4 = 1 , 63 . . . Try n = 5 : ( 1 , 13 ) 5 = 1 , 84 . . .
(30)
4. Step 4. Write the final answer : Mr Lowe should take the loan over four years (If he took the loan over five years, he would end up paying more than he wants to.)

### Other Applications of Compound Growth

The following two examples show how we can take the formula for compound interest and apply it to real life problems involving compound growth or compound decrease.

#### Exercise 7: Population Growth

South Africa's population is increasing by 2,5% per year. If the current population is 43 million, how many more people will there be in South Africa in two years' time ?

##### Solution
1. Step 1. Determine what has been provided and what is required :
• initial value (opening balance), P=43000000P=43000000
• period of time, n=2 year n=2 year
• rate of increase, i=2,5% per yeari=2,5% per year

We are required to find the final value (closing balance AA).

2. Step 2. Determine how to approach the problem :

We know from Equation 24 that:

A = P ( 1 + i ) n A = P ( 1 + i ) n
(31)
3. Step 3. Solve the problem :
A = P ( 1 + i ) n = 43 000 000 ( 1 + 0 , 025 ) 2 = 45 176 875 A = P ( 1 + i ) n = 43 000 000 ( 1 + 0 , 025 ) 2 = 45 176 875
(32)
4. Step 4. Write the final answer :

There will be 45176875-43000000=217687545176875-43000000=2176875 more people in 2 years' time

#### Exercise 8: Compound Decrease

A swimming pool is being treated for a build-up of algae. Initially, 50m250m2 of the pool is covered by algae. With each day of treatment, the algae reduces by 5%. What area is covered by algae after 30 days of treatment ?

##### Solution
1. Step 1. Determine what has been provided and what is required :
• Starting amount (opening balance), P=50m2P=50m2
• period of time, n=30 days n=30 days
• rate of decrease, i=5% per dayi=5% per day

We are required to find the final area covered by algae (closing balance AA).

2. Step 2. Determine how to approach the problem :

We know from Equation 24 that:

A = P ( 1 + i ) n A = P ( 1 + i ) n
(33)

But this is compound decrease so we can use the formula:

A = P ( 1 - i ) n A = P ( 1 - i ) n
(34)
3. Step 3. Solve the problem :
A = P ( 1 - i ) n = 50 ( 1 - 0 , 05 ) 30 = 10 , 73 m 2 A = P ( 1 - i ) n = 50 ( 1 - 0 , 05 ) 30 = 10 , 73 m 2
(35)
4. Step 4. Write the final answer :

Therefore the area still covered with algae is 10,73m210,73m2

#### Compound Interest

1. An amount of R3 500 is invested in a savings account which pays compound interest at a rate of 7,5% per annum. Calculate the balance accumulated by the end of 2 years.
2. If the average rate of inflation for the past few years was 7,3% and your water and electricity account is R 1 425 on average, what would you expect to pay in 6 years time ?
3. Shrek wants to invest some money at 11% per annum compound interest. How much money (to the nearest rand) should he invest if he wants to reach a sum of R 100 000 in five year's time ?

The next section on exchange rates is included for completeness. However, you should know about fluctuating exchange rates and the impact that this has on imports and exports. Fluctuating exchange rates lead to things like increases in the cost of petrol. You can read more about this in Fluctuating exchange rates.

## Foreign Exchange Rates - (Not in CAPS, included for completeness)

Is $500 ("500 US dollars") per person per night a good deal on a hotel in New York City? The first question you will ask is “How much is that worth in Rands?". A quick call to the local bank or a search on the Internet (for example on http://www.x-rates.com) for the Dollar/Rand exchange rate will give you a basis for assessing the price. A foreign exchange rate is nothing more than the price of one currency in terms of another. For example, the exchange rate of 6,18 Rands/US Dollars means that$1 costs R6,18. In other words, if you have $1 you could sell it for R6,18 - or if you wanted$1 you would have to pay R6,18 for it.

But what drives exchange rates, and what causes exchange rates to change? And how does this affect you anyway? This section looks at answering these questions.

### How much is R1 really worth?

We can quote the price of a currency in terms of any other currency, for example, we can quote the Japanese Yen in term of the Indian Rupee. The US Dollar (USD), British Pound Sterling (GBP) and the Euro (EUR) are, however, the most common used market standards. You will notice that the financial news will report the South African Rand exchange rate in terms of these three major currencies.

 Currency Abbreviation Symbol South African Rand ZAR R United States Dollar USD $British Pounds Sterling GBP £ So the South African Rand, noted ZAR, could be quoted on a certain date as 6,07040 ZAR per USD (i.e.$1,00 costs R6,07040), or 12,2374 ZAR per GBP. So if I wanted to spend $1 000 on a holiday in the United States of America, this would cost me R6 070,40; and if I wanted £1 000 for a weekend in London it would cost me R12 237,40. This seems obvious, but let us see how we calculated those numbers: The rate is given as ZAR per USD, or ZAR/USD such that$1,00 buys R6,0704. Therefore, we need to multiply by 1 000 to get the number of Rands per $1 000. Mathematically,$ 1 , 00 = R 6 , 0740 1 000 × $1 , 00 = 1 000 × R 6 , 0740 = R 6 074 , 00$ 1 , 00 = R 6 , 0740 1 000 × $1 , 00 = 1 000 × R 6 , 0740 = R 6 074 , 00 (36) as expected. What if you have saved R10 000 for spending money for the same trip and you wanted to use this to buy USD? How many USD could you get for this? Our rate is in ZAR/USD but we want to know how many USD we can get for our ZAR. This is easy. We know how much$1,00 costs in terms of Rands.

$1 , 00 = R 6 , 0740$ 1 , 00 6 , 0740 = R 6 , 0740 6 , 0740 $1 , 00 6 , 0740 = R 1 , 00 R 1 , 00 =$ 1 , 00 6 , 0740 = $0 , 164636$ 1 , 00 = R 6 , 0740 $1 , 00 6 , 0740 = R 6 , 0740 6 , 0740$ 1 , 00 6 , 0740 = R 1 , 00 R 1 , 00 = $1 , 00 6 , 0740 =$ 0 , 164636
(37)

As we can see, the final answer is simply the reciprocal of the ZAR/USD rate. Therefore, for R10 000 will get:

R 1 , 00 = $1 , 00 6 , 0740 10 000 × R 1 , 00 = 10 000 ×$ 1 , 00 6 , 0740 = $1 646 , 36 R 1 , 00 =$ 1 , 00 6 , 0740 10 000 × R 1 , 00 = 10 000 × $1 , 00 6 , 0740 =$ 1 646 , 36
(38)

We can check the answer as follows:

$1 , 00 = R 6 , 0740 1 646 , 36 ×$ 1 , 00 = 1 646 , 36 × R 6 , 0740 = R 10 000 , 00 $1 , 00 = R 6 , 0740 1 646 , 36 ×$ 1 , 00 = 1 646 , 36 × R 6 , 0740 = R 10 000 , 00
(39)

#### Six of one and half a dozen of the other

So we have two different ways of expressing the same exchange rate: Rands per Dollar (ZAR/USD) and Dollar per Rands (USD/ZAR). Both exchange rates mean the same thing and express the value of one currency in terms of another. You can easily work out one from the other - they are just the reciprocals of the other.

If the South African Rand is our domestic (or home) currency, we call the ZAR/USD rate a “direct" rate, and we call a USD/ZAR rate an “indirect" rate.

In general, a direct rate is an exchange rate that is expressed as units of home currency per units of foreign currency, i.e., Domestic Currency Foreign Currency Domestic Currency Foreign Currency .

The Rand exchange rates that we see on the news are usually expressed as direct rates, for example you might see:

 Currency Abbreviation Exchange Rates 1 USD R6,9556 1 GBP R13,6628 1 EUR R9,1954

The exchange rate is just the price of each of the Foreign Currencies (USD, GBP and EUR) in terms of our domestic currency, Rands.

An indirect rate is an exchange rate expressed as units of foreign currency per units of home currency, i.e. Foreign Currency Domestic Currency Foreign Currency Domestic Currency .

Defining exchange rates as direct or indirect depends on which currency is defined as the domestic currency. The domestic currency for an American investor would be USD which is the South African investor's foreign currency. So direct rates, from the perspective of the American investor (USD/ZAR), would be the same as the indirect rate from the perspective of the South Africa investor.

#### Terminology

Since exchange rates are simply prices of currencies, movements in exchange rates means that the price or value of the currency has changed. The price of petrol changes all the time, so does the price of gold, and currency prices also move up and down all the time.

If the Rand exchange rate moved from say R6,71 per USD to R6,50 per USD, what does this mean? Well, it means that $1 would now cost only R6,50 instead of R6,71. The Dollar is now cheaper to buy, and we say that the Dollar has depreciated (or weakened) against the Rand. Alternatively we could say that the Rand has appreciated (or strengthened) against the Dollar. What if we were looking at indirect exchange rates, and the exchange rate moved from$0,149 per ZAR (=16,7116,71) to $0,1538 per ZAR (=16,5016,50). Well now we can see that the R1,00 cost$0,149 at the start, and then cost $0,1538 at the end. The Rand has become more expensive (in terms of Dollars), and again we can say that the Rand has appreciated. Regardless of which exchange rate is used, we still come to the same conclusions. In general, • for direct exchange rates, the home currency will appreciate (depreciate) if the exchange rate falls (rises) • For indirect exchange rates, the home currency will appreciate (depreciate) if the exchange rate rises (falls) As with just about everything in this chapter, do not get caught up in memorising these formulae - doing so is only going to get confusing. Think about what you have and what you want - and it should be quite clear how to get the correct answer. ##### Discussion : Foreign Exchange Rates In groups of 5, discuss: 1. Why might we need to know exchange rates? 2. What happens if one country's currency falls drastically vs another country's currency? 3. When might you use exchange rates? ### Cross Currency Exchange Rates - (not in CAPS, included for completeness) We know that exchange rates are the value of one currency expressed in terms of another currency, and we can quote exchange rates against any other currency. The Rand exchange rates we see on the news are usually expressed against the major currencies, USD, GBP and EUR. So if for example, the Rand exchange rates were given as 6,71 ZAR/USD and 12,71 ZAR/GBP, does this tell us anything about the exchange rate between USD and GBP? Well I know that if$1 will buy me R6,71, and if £1.00 will buy me R12,71, then surely the GBP is stronger than the USD because you will get more Rands for one unit of the currency, and we can work out the USD/GBP exchange rate as follows:

Before we plug in any numbers, how can we get a USD/GBP exchange rate from the ZAR/USD and ZAR/GBP exchange rates?

Well,

USD / GBP = USD / ZAR × ZAR / GBP . USD / GBP = USD / ZAR × ZAR / GBP .
(40)

Note that the ZAR in the numerator will cancel out with the ZAR in the denominator, and we are left with the USD/GBP exchange rate.

Although we do not have the USD/ZAR exchange rate, we know that this is just the reciprocal of the ZAR/USD exchange rate.

USD / ZAR = 1 ZAR / USD USD / ZAR = 1 ZAR / USD
(41)

Now plugging in the numbers, we get:

USD / GBP = USD / ZAR × ZAR / GBP = 1 ZAR / USD × ZAR / GBP = 1 6 , 71 × 12 , 71 = 1 , 894 USD / GBP = USD / ZAR × ZAR / GBP = 1 ZAR / USD × ZAR / GBP = 1 6 , 71 × 12 , 71 = 1 , 894
(42)

#### Tip:

Sometimes you will see exchange rates in the real world that do not appear to work exactly like this. This is usually because some financial institutions add other costs to the exchange rates, which alter the results. However, if you could remove the effect of those extra costs, the numbers would balance again.

#### Investigation : Cross Exchange Rates - Alternative Method

If $1 = R 6,40, and £1 = R11,58 what is the$/£ exchange rate (i.e. the number of US$per £)? Overview of problem You need the$/£ exchange rate, in other words how many dollars must you pay for a pound. So you need £1. From the given information we know that it would cost you R11,58 to buy £1 and that $1 = R6,40. Use this information to: 1. calculate how much R1 is worth in$.
2. calculate how much R11,58 is worth in $. Do you get the same answer as in the worked example? ### Fluctuating exchange rates If everyone wants to buy houses in a certain suburb, then house prices are going to go up - because the buyers will be competing to buy those houses. If there is a suburb where all residents want to move out, then there are lots of sellers and this will cause house prices in the area to fall - because the buyers would not have to struggle as much to find an eager seller. This is all about supply and demand, which is a very important section in the study of Economics. You can think about this is many different contexts, like stamp-collecting for example. If there is a stamp that lots of people want (high demand) and few people own (low supply) then that stamp is going to be expensive. And if you are starting to wonder why this is relevant - think about currencies. If you are going to visit London, then you have Rands but you need to “buy" Pounds. The exchange rate is the price you have to pay to buy those Pounds. Think about a time where lots of South Africans are visiting the United Kingdom, and other South Africans are importing goods from the United Kingdom. That means there are lots of Rands (high supply) trying to buy Pounds. Pounds will start to become more expensive (compare this to the house price example at the start of this section if you are not convinced), and the exchange rate will change. In other words, for R1 000 you will get fewer Pounds than you would have before the exchange rate moved. Another context which might be useful for you to understand this: consider what would happen if people in other countries felt that South Africa was becoming a great place to live, and that more people were wanting to invest in South Africa - whether in properties, businesses - or just buying more goods from South Africa. There would be a greater demand for Rands - and the “price of the Rand" would go up. In other words, people would need to use more Dollars, or Pounds, or Euros ... to buy the same amount of Rands. This is seen as a movement in exchange rates. Although it really does come down to supply and demand, it is interesting to think about what factors might affect the supply (people wanting to “sell" a particular currency) and the demand (people trying to “buy" another currency). This is covered in detail in the study of Economics, but let us look at some of the basic issues here. There are various factors which affect exchange rates, some of which have more economic rationale than others: • economic factors (such as inflation figures, interest rates, trade deficit information, monetary policy and fiscal policy) • political factors (such as uncertain political environment, or political unrest) • market sentiments and market behaviour (for example if foreign exchange markets perceived a currency to be overvalued and starting selling the currency, this would cause the currency to fall in value - a self-fulfilling expectation). The exchange rate also influences the price we pay for certain goods. All countries import certain goods and export other goods. For example, South Africa has a lot of minerals (gold, platinum, etc.) that the rest of the world wants. So South Africa exports these minerals to the world for a certain price. The exchange rate at the time of export influences how much we can get for the minerals. In the same way, any goods that are imported are also influenced by the exchange rate. The price of petrol is a good example of something that is affected by the exchange rate. ## Foreign Exchange 1. I want to buy an IPOD that costs £100, with the exchange rate currently at £1=R14£1=R14. I believe the exchange rate will reach R12R12 in a month. 1. How much will the MP3 player cost in Rands, if I buy it now? 2. How much will I save if the exchange rate drops to R12R12? 3. How much will I lose if the exchange rate moves to R15R15? Click here for the solution 2. Study the following exchange rate table:  Country Currency Exchange Rate United Kingdom (UK) Pounds(£) R14,13R14,13 United States (USA) Dollars ($) R7,04R7,04
1. In South Africa the cost of a new Honda Civic is R173400R173400. In England the same vehicle costs £12200£12200 and in the USA $2190021900. In which country is the car the cheapest when you compare the prices converted to South African Rand ? 2. Sollie and Arinda are waiters in a South African restaurant attracting many tourists from abroad. Sollie gets a £6£6 tip from a tourist and Arinda gets$ 12. How many South African Rand did each one get ?

## Summary

• There are two types of interest: simple and compound.
• The following table summarises the key definitions that are used in both simple and compound interest.
 P P Principal (the amount of money at the starting point of the calculation) A A Closing balance (the amount of money at the ending point of the calculation) i i interest rate, normally the effective rate per annum n n period for which the investment is made
• For simple interest we use:
A = P ( 1 + i · n ) A=P ( 1 + i · n )
(45)
• For compound interest we use:
A = P ( 1 + i ) n A=P ( 1 + i ) n
(46)
• The formulae for simple and compound interest can be applied to many everyday problems.
• A foreign exchange rate is the price of one currency in terms of another.

### Tip:

Always keep the interest and the time period in the same units of time (e.g. both in years, or both in months etc.).

The following three videos provide a summary of how to calculate interest. Take note that although the examples are done using dollars, we can use the fact that dollars are a decimal currency and so are interchangeable (ignoring the exchange rate) with rands. This is what is done in the subtitles.

Figure 1
Khan academy video on interest - 1

Figure 2
Khan academy video on interest - 2

Note in this video that at the very end the rule of 72 is mentioned. You will not be using this rule, but will rather be using trial and error to solve the problem posed.

Figure 3
Khan academy video on interest - 3

## End of Chapter Exercises

1. You are going on holiday to Europe. Your hotel will cost 200 euros per night. How much will you need in Rands to cover your hotel bill, if the exchange rate is 1 euro = R9,20?
2. Calculate how much you will earn if you invested R500 for 1 year at the following interest rates:
1. 6,85% simple interest.
2. 4,00% compound interest.
3. Bianca has R1 450 to invest for 3 years. Bank A offers a savings account which pays simple interest at a rate of 11% per annum, whereas Bank B offers a savings account paying compound interest at a rate of 10,5% per annum. Which account would leave Bianca with the highest accumulated balance at the end of the 3 year period?
4. How much simple interest is payable on a loan of R2 000 for a year, if the interest rate is 10%?
5. How much compound interest is payable on a loan of R2 000 for a year, if the interest rate is 10%?
6. Discuss:
1. Which type of interest would you like to use if you are the borrower?
2. Which type of interest would you like to use if you were the banker?
7. Calculate the compound interest for the following problems.
1. A R2 000 loan for 2 years at 5%.
2. A R1 500 investment for 3 years at 6%.
3. An R800 loan for l year at 16%.
8. If the exchange rate for 100 Yen = R 6,2287 and 1 Australian Doller (AUD) = R 5,1094 , determine the exchange rate between the Australian Dollar and the Japanese Yen.
9. Bonnie bought a stove for R 3 750. After 3 years she had finished paying for it and the R 956,25 interest that was charged for hire-purchase. Determine the rate of simple interest that was charged.

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