Transcript The Laws Of Surds.
The Laws Of Surds.
3
5 11
2 5 3 7
9 3 21
7 11 3 7
10 3 5 13
What Is A Surd ?
Calculate the following roots:
( 1 )
= 6
36 ( 2 ) 3 8
= 2
( 3 ) 4 81
= 3
( 4 ) 3 125
= 5
( 5 ) 5 32
= 2 All of the above roots have exact values and are called rational . Now use a calculator to estimate the following roots:
( 1 ) 2
1 .
41 ( 2 ) 3 21
2 .
76 ( 3 ) 4 100
3 .
16 ( 4 ) 83
9 .
11
All these roots do not have exact values and are called irrational .
They are called surds.
Adding & Subtracting Surds.
Because a surd such as 2 cannot be calculated exactly it can be treated in the same way as an “x” variable in algebra. The following examples will illustrate this point.
Simplify the following:
( 1 ) 4 2
6 2
10 2 ( 2 ) 16
9 23 23
7 23
4 x + 6x = 10x
( 3 ) 10
13 3
7 3 3
4 3 ( 4 ) 8
4
16 x - 7x = 9x
17
12 17 17
Simplifying Square Roots.
Some square roots can be broken down into a mixture of integer values and surds. The following examples will illustrate this idea: Simplify: (1)
12
= 4 x 3 = 2 3 To simplify 12 we must split 12 into factors but at least one of the factors used must have an exact square root. Now simplify the square root.
From this example it can be appreciated that you must use the square numbers as factors in order to simplify the square root. The square numbers are: 4,9,16,25,36,49,64,81,100,121,144,169,196,225…
(2)
45
=
9 x
5
= 3 5 (4) 2700 = 100 x
27
= 10 x 9 x 3 = 10 x 3 x 3 = 30
3
(3) 32 =
16 x
2
= 4 2 (3) 72 = 4 x 18 = 2 x 9 x 2 = 2 x 3 x
2
= 6
2
This example demonstrates the need to keep looking for further simplification. Using 36 would have saved time
What Goes In The Box ? 1
Simplify the following square roots: (1)
20
(2)
27
(3)
48
= 2
5
= 3
3
= 4
3
(4)
75
= 5
3
(5)
4500 = 30
5
(6)
3200 = 40
2
Rationalising Surds.
You may recall from your fraction work that the top line of a fraction is the numerator and the bottom line the denominator.
2 3
numerator deno
min
ator
.
Fractions can contain surds:
3 2 4 5 7 3 3
2 5
If by using certain maths techniques we remove the surd from either the top or bottom of the fraction then we say we are “rationalising the numerator” or “rationalising the denominator”.
(
To rationalise the denominator in the following multiply the top and bottom of the fraction by the square root you are trying to remove:
1 ) 3 3 5 3 5
x
5 5 5 5 3 5
5 5
3 ( 2 ) 2 7 2 3
7
7 7
3 7 2
7
3 14 7 ( 3 ) 7 10 5
7 10
5
5 5
10 7
5
2 7 5 5
5 x 5 = 25 = 5
What Goes In The Box ? 2.
Rationalise the denominator of the following expressions:
( 1 ) 7 3
7 3 3 ( 4 ) 9 4 2
2 9 2 ( 2 ) 4 6
2 3 6 2 ( 5 ) 7 5 3
2 15 21 ( 3 ) 3 14 10
7 10 15 6 ( 6 ) 11 3 2
3 11 6
Conjugate Pairs.
Consider the expression below:
( 3
6 )( 3
6 )
This is a conjugate pair. The brackets are identical apart from the sign in each bracket .
Now observe what happens when the brackets are multiplied out:
( 3
6 )( 3
6 )
=
3 X
3 - 6 3 + 6 3 - 36 = 3 - 36 = -33 When the brackets are multiplied out the surds cancel out and we end up seeing that the expression is rational . This result is used throughout the following slide.
Rationalise the denominator in the expressions below by multiplying top and bottom by the appropriate conjugate:
( 1 ) 2 5
3 ( 2 ) ( 3 7
2 )
( 5 2 ( 5
3 )
3 )( 5
3 )
( 5
2 ( 5 ( 5
9 ) 3 )
( 5
3 ) 2 2 ( 5
3 5
3 ) 5
5
9 )
( 7 ( 3
2 3
)( 2 ) 3
7 ( 3 ( 3
2 ) 2 )
7 ( 3
2 ) 2 )
In both of the above examples the surds have been removed from the denominator as required.
What Goes In The Box ? 3.
Rationalise the denominator in the expressions below :
( 1 ) ( 7 5
2 )
5 ( 7
2 ) 3 ( 2 ) ( 3
3 2 )
3
6 ( 3 )
7 ( ( 2 7 5
4 ) 5
2 ) 2
Rationalise the numerator in the expressions below :
( 4 ) 6
4 12
6 (
5 6
4 ) ( 5 ) 5
7 11
7 (
6 5
11 ) ( 6 ) 2 3
6
1 33 3 11