4.6 SPM Practice (Long Questions)


Question 1:
(a) State if each of the following statements is true or false.
 (i) (i)  2 4 =16  and  12÷ 27 3 =3.
 (ii) 17 is a prime number or an even number.

(b) Complete the statement, in the answer space, to form a true statement by 
using the quantifier ‘all’ or ‘some’.

(c) Write down two implications based on the following statement:


A number is a prime number if and only if it is only divisible by 1 and itself.
Solution:
(a)(i) False
(a)(ii) True

(b)   Some   multiples of 3 are multiples of 6.

(c) Implication 1: If a number is a prime number, then it is only divisible by 1 and itself.
 Implication 2: If a number is only divisible by 1 and itself, then it is a prime
 number.


Question 2:
(a) State if each of the following statements is true or false.
  (i)  2 × 3 = 6 or 2 + 3 = 6
  (ii) 2 is a prime number and 5 is an even number.

(b) Write down the converse of the following implication.

  Hence, state whether the converse is true or false.

If x is a multiple of 12,
then x is a multiple of 3.
(c) Complete the premise in the following argument:

Premise 1: All hexagons have six sides
Premise 2: _____________________
Conclusion: ABCDEF has six sides.
Solution:
(a)(i) True
(a)(ii) False

(b) Converse: If x is a multiple of 3, then x is a multiple of 12.
  The converse is false.

(c) Premise 2: ABCDEF is a hexagon.

4.6 SPM Practice (Long Questions)


Question 3:
(a) Complete each of the following statements with the quantifier ‘all’ or ‘some’ so that it will become a true statement.
  (i) ___________ of the prime numbers are odd numbers.
 (ii) ___________ pentagons have five sides.

(b) Write down two implications based on the following statement:


AB = B if and only if A υ B = A.
(c) Complete the premise in the following argument:

Premise 1: If a number is a factor of 24, then it is a factor of 48.
Premise 2: 12 is a factor of 24.
Conclusion: _____________________

Solution:
 (a)(i)    Some  of the prime numbers are odd numbers.
 (a)(ii)  All pentagons have five sides.

(b) Implication 1: If AB = B, then A υ B = A.
  Implication 2: If A υ B = A, then AB = B.

(c)
 Conclusion: 12 is a factor of 48.


Question 4:
(a) Combine the following two statements to form one true statement.
  Statement 1: (– 3)² = 9
  Statement 2: –3 (3) = 19
(b) Complete the premise in the following argument:

Premise 1: _____________________
Premise 2: x is a multiple of 25.
Conclusion: x is a divisible of 5.
(c) Make a general conclusion by induction for the sequence of numbers 7, 14, 27, … which follows the following pattern.
7 = 3 (2)1 + 1
14 = 3 (2)2 + 2
27 = 3 (2)3 + 3
…. = ………..
Solution:
(a) (– 3)² = 9 or –3 (3) = 19.

(b) Premise 1: All multiples of 25 is divisible by 5.

(c) 3 (2)n + n, where n = 1, 2, 3, …

4.2 Quantifiers ‘All’ and ‘Some’ (Sample Questions)

Example 1:
Complete each of the following statements using the quantifiers ‘all’ or ‘some’ to make the statement true.
(a) _____ rectangles are squares.
(b) _____ prime numbers are odd numbers.
(c) _____ triangles have equal sides.
(d) _____ even numbers are divisible by 2.

Answer
:
(a) Some rectangles are squares.
(b) Some prime numbers are odd numbers.
(c) Some triangles have equal sides.
(d) All even numbers are divisible by 2.



Example 2:
Construct a true statement using the quantifier ‘all’ or ‘some’ for the given object and property.
(a) Object: multiples of 4
 Property: can be divided exactly by 5
(b) Object: regular hexagon
 Property: 6 equal sides
(c) Object: acute angles
 Property: less than 90o

Answer:
(a) Some multiples of 4 can be divided exactly by 5.
(b) All regular hexagons have 6 equal sides.
(c) All acute angles are less than 90o.

4.5 Arguments (Short Notes)

4.5 Arguments

(A) Premises and Conclusions
1. An argument is a process of making conclusion based on several given statements.
2. The statements given are known as premises.
3. An argument consists of premises and a conclusion.

Example 1:

Identify the premises and conclusion of the following argument.
(a) A pentagon has 5 sides. ABCDE is a pentagon. Therefore, ABCDE has 5 sides.

Solution:
Premise 1: A pentagon has 5 sides.
Premise 2: ABCDE is a pentagon.
Conclusion: ABCDE has 5 sides.


(B) Forms of Arguments
1. Based on two given premises, a conclusion can be made for three different forms of arguments.

Argument Form I
Premise 1: All A are B.
Premise 2: C is A.
Conclusion: C is B.
Example 2:
Make a conclusion based on the two premises given below.
Premise 1: All multiples of 5 are divisible by 5.
Premise 2: 45 is a multiple of 5.
Conclusion: ______________

Solution:
Conclusion: 45 is divisible by 5.

Argument Form II
Premise 1: If p, then q.
Premise 2: p is true.
Conclusion: q is true.
Example 3:
Make a conclusion based on the two premises given below.
Premise 1: If a number is a factor of 18, then the number is a factor of 54.
Premise 2: 3 is a factor of 18.
Conclusion: ______________

Solution:
Conclusion: 3 is a factor of 54.

Argument Form III
Premise 1: If p, then q.
Premise 2: Not q is true.
Conclusion: Not p is true.

Example 4:
Make a conclusion based on the two premises given below.
Premise 1: If P is a subset of Q, then P  Q = P.
Premise 2P  Q  P
Conclusion: ______________

Solution:
Conclusion: P is not the subset of Q.

4.4 Implication

(A) Antecedent and Consequent of an Implication

  1. For two statements p and q, the sentence ‘if p, then q’ is called an implication.
  2. p is called the antecedent.
    q is called the consequent.


Example:

Identify the antecedent and consequent of the following implications.

(a) If m = 2, then 2m2 + m = 10

(b) I f P Q = P , t h e n Q P

Solution:

  1. Antecedent: m = 2
    Consequent: 2m2 + m = 10
  2. Antecedent : P Q = P Consequent : Q P

(B) Implications of the Form ‘p if and only if q

  1. Two implications ‘if p, then q and ‘if q, then p can be written as ‘p if and only if q.
  2. Likewise, two statements can be written from a statement in the form ‘p if and only if q as follows:
    Implication 1: If p, then q.
    Implication 2: If q, then p.


Example 1:

Given that p: x + 1 = 8
q: x = 7
Construct a mathematical statement in the form of implication

  1. If p, then q.
  2. p if and only if q.

Solution:

  1. If x + 1 = 8, then x = 7.
  2. x + 1 = 8 if and only if x = 7.

Example 2:

Write down two implications based on the following sentence:
x3 = 64 if and only if x = 4.

Solution:

If x3 = 64, then x = 4.
If x = 4, then x3 = 64.

(C) Converse of an Implication

  1. The converse of an implication ‘if p, then q’ is if q, then p’.

Example:

State the converse of each of the following implications.

  1. If x2 + x – 2 = 0, then (x – 1)(x + 2) = 0.
  2. If x = 7, then x + 2 = 9.

Solution:

  1. If (x – 1)(x + 2) = 0, then x2 + x – 2.
  2. If x + 2 = 9, then x = 7.

 

 

4.6 SPM Practice (Long Questions)


Question 7:
(a)(i) State whether the following compound statement is true or false.

3 + 3 = 9 or   3 × 3 = 9
(a)(ii) Determine whether the following converse is true or false.

If x > 3, then x > 7
(b) Write down Premise 2 to complete the following argument:
Premise 1: If y = mx + 5 is a linear equation, then m is a gradient of the straight line.
Premise 2: _____________________
Conclusion: 2 is the gradient of the straight line.

(c) Angle subtended at the centre of a regular polygon with n sides is 360 o n .
Make one conclusion by deduction for the angle subtended at the centre of a regular polygon with 5 sides.

Solution:
(a)(i) True

(a)(ii)
The converse is true

(b) Premise 2: y = 2x + 5 is a linear equation

(c)
Angle subtended at the centre of a regular pentagon = 360 o n = 360 o 5 = 72 o


Question 8:
(a) State whether the following sentence is a statement or not a statement.

x + 7 = 9
(b) Complete the following compound statement by writing the word ‘or’ or ‘and’ to form a true statement.
23 = 6 …… 5 × 0 = 0

(c) Write down Premise 2 to complete the following argument:
Premise 1: All isosceles triangles have two equal sides.
Premise 2: _____________________
Conclusion: ABC has two equal sides.

(d) Make a general conclusion by induction for the sequence of numbers 1, 7, 17, 31, … which follows the following pattern.
1 = (2 × 1) – 1
7 = (2 × 4) – 1
17 = (2 × 9) – 1
31 = (2 × 16) – 1

Solution:
(a) Not a statement

(b) 23 = 6 …or… 5 × 0 = 0

(c) ABC is an isosceles triangle.

(d)
1 = (2 × 1) – 1 =  (2 × 12) – 1
7 = (2 × 4) – 1 =  (2 × 22) – 1
17 = (2 × 9) – 1 =  (2 × 32) – 1
31 = (2 × 16) – 1 =  (2 × 42) – 1
  =  2n2 – 1, n = 1, 2, 3, …

4.5 Arguments

(A) Premises and Conclusions

  1. An argument is a process of making conclusion based on several given statements.
  2. The statements given are known as premises.
  3. An argument consists of premises and a conclusion.

Example 1:

Identify the premises and conclusion of the following argument.

  1. A pentagon has 5 sides. ABCDE is a pentagon. Therefore, ABCDE has 5 sides.

Solution:

Premise 1: A pentagon has 5 sides.
Premise 2: ABCDE is a pentagon.
Conclusion: ABCDE has 5 sides.

(B) Forms of Arguments

  1. Based on two given premises, a conclusion can be made for three different forms of arguments.

Argument Form I

Premise 1: All A are B.
Premise 2: C is A.
Conclusion: C is B.

Example 2:

Make a conclusion based on the two premises given below.

Premise 1: All multiples of 5 are divisible by 5.
Premise 2: 45 is a multiple of 5.
Conclusion:  _______________

Solution:

Conclusion: 45 is divisible by 5.

Argument Form II

Premise 1: If p, then q.
Premise 2: p is true.
Conclusion: q is true.

Example 3:

Make a conclusion based on the two premises given below.
Premise 1: If a number is a factor of 18, then the number is a factor of 54.
Premise 2: 3 is a factor of 18.
Conclusion:  _______________

Solution:

Conclusion: 3 is a factor of 54.

Argument Form III

Premise 1: If p, then q.
Premise 2: Not q is true.
Conclusion: Not p is true.

Example 4:

Make a conclusion based on the two premises given below.
Premise 1: If P is a subset of Q, then PQ = P .
Premise 2: PQP
Conclusion:  _______________

Solution:

Conclusion: P is not the subset of Q.

 

 

4.6 SPM Practice (Long Questions)

Question 5:
(a) State if each of the following statements is true or false.
 (i)    23= 8 or ⅓ = 1.33.
 (ii)  – 6 > – 8 and 6 > 8.
 
(b) Write down two implications based on the following statement:

x a + y b =1 if and only if bx+ay=ab.

(c) It is given that the interior angle of a regular polygon of n sides 
  is   ( 1 2 n ) × 180 .
  Make one conclusion by deduction on the size of the interior angle of a regular hexagon.

Solution:

(a)(i) True

(a)(ii) False

(b) 

Implication 1:   If   x a + y b =1, then bx+ay=ab. _ Implication 2:   If  bx+ay=ab, then  x a + y b =1. _

(c)
Size of an interior angle of a regular hexagon = ( 1 2 6 ) × 180 = 2 3 × 180 = 120


Question 6:
(a) Complete the following mathematical sentence by writing the symbol > or <.
  (i) 53____ 20 is a false statement.
  (ii) – 3 ____ – 10 is a true statement.

(b) Complete the conclusion in the following argument:
 Premise 1 : If  n 1 2 = n , then  4 1 2 = 4 =2.   Premise 2 :  n 1 2 = n  Conclusion : _____________________
(c) Make a general conclusion by induction for the sequence of numbers 10, 35, 70, … which follows the following pattern.

10 = 5 (2)2 – 10 
35 = 5 (3)2 – 10
70 = 5 (4)2 – 10
…. = ………..

Solution:
(a)(i) 53   <    20 is a false statement.

(a)(ii)   – 3    >    – 10 is a true statement.

(b)

Conclusion : 4 1 2 = 4 = 2

(c) 5 (n + 1)2 – 10, where n = 1, 2, 3, …


4.4 Implications Short Notes

4.4 Implications

(A) Antecedent and Consequent of an Implication
1. For two statements p and q, the sentence ‘if p, then q’ is called an implication.

2. p is called the antecedent.
   q is called the consequent.

Example:
Identify the antecedent and consequent of the following implications.
(a) If m = 2, then 2m2 + m = 10
(b) If PQ=P, then QP

Solution:
(a) Antecedent: m = 2
Consequent:2m2 + m = 10

(b) Antecedent:PQ=P       Consequent:QP


(B) Implications of the Form ‘p if and only if q
1. Two implications ‘if p, then q’ and ‘if q, then p’ can be written as ‘p if and only if q’.
2. Likewise, two statements can be written from a statement in the form p if and only if q as follows:
Implication 1: If p, then q.
Implication 2: If q, then p.

Example 1:
Given that p: x + 1 = 8
 q: x = 7
Construct a mathematical statement in the form of implication
(a) If p, then q.
(b) p if and only if q.

Solution:
(a) If x + 1 = 8, then x = 7.
(b) x + 1 = 8 if and only if x = 7. 

Example 2:
Write down two implications based on the following sentence:
x3 = 64 if and only if x = 4.

Solution:
If x3 = 64, then x = 4.
If x = 4, then x3 = 64.



(C) Converse of an Implication
1. The converse of an implication ‘if p, then q’ is ‘if q, then p’.
 
Example:
State the converse of each of the following implications.
(a) If x2 + x – 2 = 0, then (x - 1)(x + 2) = 0.
(b) If x = 7, then x + 2 = 9.

Solution:
(a) If (x - 1)(x + 2) = 0, then x2 + x – 2.
(b) If x + 2 = 9, then x = 7.

4.1 Statements

(A) Determine Whether a Given Sentence is a Statement
1. A statement is a sentence which is either true or false but not both.

2. Sentences which are questions, instructions and exclamations are not statements.

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

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



(B) Determine Whether a Statement is True or False.

Example 2:
Determine whether each of the following statements is true or false.
(a) 7 is a prime number
(b) -10 > -7
(c) 3 is a factor of 8.

Solution:
(a) True
(b) False
(c) False



(C) Constructing Statements Using Numbers and Symbols
 
1. True and false statements can be constructed with numbers and mathematical symbols.
 
Example 3:
Construct (i) a true statement, (ii) a false statement,
using the following numbers and mathematical symbols.
(a) 2, 4, 8, ×, =
(b) {a, b, c}, {d} , U =

Solution:
(a)(i) A true statement: 2 × 4 = 8
(a)(ii) A false statement: 2 × 8 = 4
(b)(i) A true statement: {d} U {a, b, c} = {a, b, c, d}
(b)(ii) A false statement: {d} U {a, b, c} = {d}