5.3 Intercepts

5.3 Intercepts
 
1. The x-intercept is the point of intersection of a straight line with the x-axis.
2. The y-intercept is the point of intersection of a straight line with the y-axis.

3. In the above diagram, the x-intercept of the straight line PQ is 6 and the y-intercept of PQ is 5.
 
4. If the x-intercept and y-intercept of a straight line are given,
  Gradient, m = y intercept x intercept

5.1 Gradient of a Straight Line


5.1 Gradient of a Straight Line
The gradient of a straight line is the ratio of the vertical distance to the horizontal distance between any two given points on the straight line.

Gradient, m = Vertical distance Horizontal distance
Example:












Find the gradient of the straight line above.

Solution
:
Gradient, m = Vertical distance Horizontal distance = 4 units 6 units = 2 3

5.2 Gradient of a Straight Line in Cartesian Coordinates (Sample Questions)


Example 1:
Given that a straight line passes through points (-3, -7) and (4, 14). What is the gradient of the straight line?

Solution:

Let (x1, y1) = (-3, -7) and (x2, y2) = (4, 14).

Gradient of the straight line 
= y 2 y 1 x 2 x 1 = 14 ( 7 ) 4 ( 3 ) = 21 7 = 3


Example 2:


The gradient of the straight line PQ in the diagram above is

Solution:
Let (x1, y1) = (12, 0) and (x2, y2) = (0, 7).

Gradient of the straight line PQ
= y 2 y 1 x 2 x 1 = 7 0 0 12 = 7 12


Example 3:
A straight line with gradient -3 passes through points (-4, 6) and (-1, p). Find the value of p.

Solution:
y 2 y 1 x 2 x 1 = 3 p 6 1 ( 4 ) = 3 p 6 3 = 3 p 6 = 9 p = 3

5.4 Equation of a Straight Line (Sample Questions)


Example 1:
Given that the equation of a straight line is 4x + 6y – 3 = 0. What is the gradient of the line?

Solution:
4x + 6y – 3 = 0
6y  = – 4x + 3
y = 4 x 6 + 3 6 y = 2 3 x + 1 2 y = m x + c g r a d i e n t , m = 2 3  


Example 2:
Given that the equation of a straight line is y = – 7x + 3. Find the y-intercept of the line?

Solution:
y = mx + c, c is y-intercept of the straight line.
Therefore for the straight line y = – 7x + 3,
y-intercept is 3


Example 3
:

 
 
 
 






Find the equation of the straight line MN if its gradient is equal to 3.
 
Solution:
Given m = 3
Substitute m = 3 and (-2, 5) into y = mx + c.
5 = 3 (-2) + c
5 = -6 + c
c = 11
Therefore the equation of the straight line MN is y = 3+ 11 

5.5 Parallel Lines (Sample Questions)


Example 1:

















The straight lines MN and PQ in the diagram above are parallel. Find the value of q.

Solution:
If two lines are parallel, their gradients are equal.
m1 = m2
mMN = mPQ

using gradient formula y 2 y 1 x 2 x 1 9 4 5 ( 1 ) = q ( 5 ) 5 ( 7 ) 5 6 = q + 5 12
60 = 6q + 30
6q = 30
q = 5

5.5 Parallel Lines (Part 1)

5.5 Parallel Lines (Part 1)
 
(A) Gradient of parallel lines

1. Two straight lines are 
parallel if they have
the same gradient.
If PQ // RS,
then mPQ = mRS
   
2. If two straight lines have 
the same gradient, then  
they are parallel. 
If mAB = mCD
then AB // CD


Example 1:
Determine whether the two straight lines are parallel.
(a) 2y – 4x = 6
  y = 2x 5
(b) 2y = 3x 4
  3y = 2x +12
 
Solution:
(a) 
2y – 4x = 6
2y = 6 + 4x
= 2x + 3,   m1= 2
= 2x 5,   m2 = 2
m1= m2
Therefore, the two straight lines are parallel.
 
(b)
2y=3x4 y= 3 2 x2,    m 1 = 3 2 3y=2x+12 y= 2 3 x+4,    m 2 = 2 3 m 1 m 2  The two straight lines are not parallel.

5.6 SPM Practice (Short Questions)


5.6.2 The Straight Line, SPM Paper 1 (Short Questions)

Question 6:
Diagram below shows a straight line RS with equation 3y = –px – 12, where p is a constant.
 

It is given that OR: OS = 3 : 2.
Find the value of p.

Solution:
Method 1:
Substitute x= –6 and y = 0 into 3y = –px – 12:
3(0) = –p (–6) – 12
0 = 6p – 12
–6p = –12
p = 2

Method 2:
OR: OS = 3 : 2
O R O S = 3 2 6 O S = 3 2 O S = 6 × 2 3 = 4 units  

Coordinates of = (0, –4)
Gradient of the straight line RS = 4 6 = 2 3  

Given 3y = –px – 12
Rearrange the equation in the form y = mx + c
y = p 3 x 4 Gradient of the straight line R S = P 3 P 3 = 2 3 P = 2



Question 7:

 
The above diagram shows two straight lines, KL and LM, on a Cartesian plane. The distance KL is 10 units and the gradient of LM is 2. Find the x-intercept of LM.

Solution:


Let point be = (0, 2).
Using Pythagoras’ Theorem,
 LN = √102 – 62 = 8
Point L = (0, 2 + 8) = (0, 10)
y-intercept of LM = 10
 
Using the gradient formula, m = y-intercept x-intercept 2 = ( 10 x-intercept ) x-intercept of L M = 10 2 = 5  

4.3 Operations on Statements (Sample Questions 1)


Example 1:
Form a compound statement by combining two given statements using the word ‘and’.
(a) × 12 = 36
 7 × 5 = 35

(b)
5 is a prime number.
 5 is an odd number.

(c)
Rectangles have 4 sides.
 Rectangles have 4 vertices.

Solution:

(a) × 12 = 36 and 7 × 5 = 35
(b) 5 is a prime number and an odd number.
(c) Rectangles have 4 sides and 4 vertices.



Example 2:
Form a compound statement by combining two given statements using the word ‘or’.
(a) 16 is a perfect square. 16 is an even number.
(b) 4 > 3.  -5 < -1

Solution:
(a) 16 is a perfect square or an even number.
(b) 4 > 3 or -5 < -1.

4.1 Statements (Sample Questions)


Example 1:
Determine whether the following sentences are statements or not. Give a reason for your answer.
(a) 3 + 3 = 8
(b) 9 – 4 = 5
(c) A pentagon has 5 sides.
(d) 4 is a prime number.
(e) Is 40 divisible by 3?
(f) Find the perimeter of a square with each side of 4 cm.
(g) Help!

Answer
:

(a) Statement; it is a false statement.
(b) Statement; it is a true statement.
(c) Statement; it is a true statement.
(d) Statement; it is a false statement.
(e) Not a statement; it is a question.
(f) Not a statement; it is an instruction.
(g) Not a statement; it is an exclamation.





Deduction and Induction

4.6 Deduction and Induction

(A) Reasoning by Deduction and Induction
1. Reasoning by deduction is a process of making a conclusion for a specific case based on a given general statement.

2. 
Reasoning by induction is a process of making a generalization based on specific cases.

Maths Tip
1. General statement  →  Special conclusion  → Deduction
2. Specific cases  →  General conclusion  →  Induction
Example: 
Determine whether the following conclusion is made based on a deductive reasoning or inductive reasoning.

(a) 
Area of triangle = ½ × Base × Height
(i) 

Area of ∆ ABC
= ½ × 7cm × 5cm
= 17.5 cm2 
  
(ii)

Area of ∆ DEF
= ½ × 7cm × 4cm
= 14 cm2
  
(b)
1 = 7 (1)2 – 6
22 = 7 (2)2 – 6
57 = 7 (3)2 – 6
106 = 7 (4)2 – 6
 7n2 – 6, n = 1, 2, 3, 4…
 
Solution: 
(a)
The specific conclusion is made based on a general statement ~ Area of triangle = ½ × Base × Height. Therefore, the conclusion is made based on deductive reasoning.

(b)
 
The general conclusion 7n2 – 6, n = 1, 2, 3, 4… is made based on specific cases. Therefore, the conclusion is based on inductive reasoning.