Chapter 2 Algebra Part 1 Section 2.1 Expansion (Revision) In Mathematics EXPANSION really means MULTIPLY. For example 3(2x + 4) can be expanded by multiplying them out. Remember: There is an invisible multiplication sign between the outside number and the opening bracket. Therefore 3(2x + 4) is really 3 (2x+4) You expand by multiplying everything inside the bracket by what is outside the bracket. Example 1) 3(2x + 4) = 3 (2x+4) = (3 2x) + (3 4) = 6x + 12 2) 4y 2 (2y + 3) = 4y 2 (2y + 3) = (4y 2 2y) + (4y 2 3) = 8y 3 + 12y 2 3) -3(2 + 3x) = -3 (2 + 3x) = (-3 2) + (-3 3x) = -6 9x [Note: The sign changes when a minus is outside the brackets] Consolidation 1) 2(3 + m) 2) t (t + 4) 3) 5h(3h 2) 4) 3d (5d 2 d 3 ) 5) 2m 2 (4m + m 2 ) c.azzopardi.smc@gmail.com 1
Expand and Simplify When two brackets are expanded there are often like terms that can be collected together. Algebraic expressions should always be simplified as much as possible. Example 1) 3(4 + m) + 2(5 + 2m) = 12 + 3m + 10 + 4m = 22 + 6m 2) 3t(5t + 4) 2t(3t 5) = 15t 2 + 12t 6t 2 + 10t = 9t 2 + 22t Consolidation: Expand and Simplify the following:- 1) 4a(2b + 3c) + 3b(3a + 2c) 2) 3y(4w + 2t) + 2w(3y 4t) 3) 5m(2n 3p) 2n(3p 2m) 4) 2r(3r + r 2 ) 3r 2 (4 2r) 5) 4e(3e 5) 2e(e 7) 6) 3k(2k + p) 2k(3p 2m) 7) 2y(3 + 4y) + y(5y 1) c.azzopardi.smc@gmail.com 2
Quadratic Expansion A quadratic expression is one which the highest power of the terms is 2. For example: y 2 2d 2 + 4d 5m 2 + 3m 2 In the expansion method, split the terms in the first set of brackets, make each of them multiply both terms in the second set of brackets, and then simplify the outcome. Example (x + 3)(x + 4) = x (x + 4) + 3 (x + 4) = x2 + 4x + 3x + 12 = x2 + 7x + 12 Example 1) (y- 2)(y + 5) = y (y + 5) 2 (y + 5) = y 2 + 5y 2y 10 = y 2 + 3y 10 2) (2t + 3)(3t + 1) = 2t (3t + 1) + 3 (3t + 1) = 6t 2 + 2t + 9t + 3 = 6t 2 + 11t + 3 c.azzopardi.smc@gmail.com 3
3) (x + 3)2 = (x + 3)(x + 3) = x (x+ 3) + 3 (x+ 3) = x 2 + 3x + 3x + 9 = x 2 + 6x + 9 Consolidation: Expand and Simplify the following:- 1) (w + 3)(w - 1) 2) (p - 2)(p - 1) 3) (7 + g)(7 - g) 4) (4 + 3p)(2p + 1) 5) (3g - 2)(5g - 2) 6) (3 2q)(4 + 5q) c.azzopardi.smc@gmail.com 4
7) (1 3p)(3 + 2p) 8) (m + 4) 2 9) (4t + 3) 2 10) (m - n) 2 11) (x - 2) 2 4 Support Exercise Pg 107 Exercise 8A No 1 4 Pg 110 Exercise 8C No 1 4 Section 2.2 Factorisation by taking out the common factor Factorisation is the process of putting mathematical expressions into brackets. It is the opposite of expansion. If we write the very first expression that you saw backwards, then we have factorised it: 5 (x + 2) = 5x + 10 c.azzopardi.smc@gmail.com 5
In this case, we look at the terms (two of them in this case, although they could be more) and we find something that divides into BOTH of them. This is written outside the brackets, and the rest of each term (with the appropriate + or - sign) is written inside. In order to do this we must find the HCF of the terms. Example 1) 6m + 12t = 6(m + 2t) 2) 5g 2 + 3g = g(5g + 3) 3) 8abc + 6bed = 2b(4ac + 3ed) [We sometimes have both a letter and number which are common] 4) 6mt 2 3mt + 9m 2 t = 3mt(2t 1 + 3m) Consolidation: Factorise the following:- 1) 9t + 3p 2) mn + 3n 3) 3m 2 3mp 4) 5b 2 c 10bc 5) 6ab + 9bc + 3bd 6) 5t 2 + 4t + at c.azzopardi.smc@gmail.com 6
7) 8ab 2 + 2ab 4a 2 b 8) 10pt 2 + 15pt + 5p 2 t Support Exercise Pg 108 Exercise 8B No 1 2 Section 2.3 Factorising by Grouping Like Terms In the previous section, whilst factorizing, the common factor was always a single term (e.g. 3, 4a, ab, etc ) The common factor does not always have to be a single term, it can be a sum or difference of terms (e.g. x + 2, 3x 4) Example 1. 2(x 4) + x(x 4) [(x - 4) can be considered as a common term] (x 4)(2 + x) We can have an expression which has both a number and a sum or difference which are common. 2. 12(x + 2) 2-9(x + 2) [(x + 2) can be considered as a common term] 3 4 (x + 2)(x + 2) 3 3 (x + 2) [3 and (x + 2) are both factors] 3(x + 2)[4(x + 2) 3] [So write 3(x + 2) outside the square brackets] 3(x + 2)[4x + 8 3] [Simplify the terms inside the square brackets] 3(x + 2)(4x + 5) c.azzopardi.smc@gmail.com 7
3. 10x(x 5) 5(x 5) 2 5 2 x (x 5) 5 (x 5) (x 5) 5(x 5)[2x (x 5)] 5(x 5)(2x x + 5) 5(x 5)(x + 5) Consolidation: Factorise the following completely:- 1. a(b + c) d(b + c) 2. y(x 6) + 2(x 6) 3. 6(x +3) 2 3(x + 3) 4. (y + 2) 2 4(y + 2) c.azzopardi.smc@gmail.com 8
When four or more terms come together to form an expression, you always look for a greatest common factor first. If you can t find a factor common to all the terms at the same time, your other option is grouping. To group, you take the terms two at a time and look for common factors for each of the pairs on an individual basis. After factoring, you see if the new groupings have a common factor. The best way to explain this is to demonstrate the factoring by grouping on a few examples. Example: 1. The four terms don t have a common factor. However, the first two terms have a common factor of and the last two terms have a common factor of 3: Notice that you now have two terms, not four, and they both have the factor (x 4). Now, factoring (x 4) out of each term, you have Factoring by grouping only works if a new common factor appears the exact same one in each term. 2. Now, consider the expression 7x + 14y + bx + 2by. Clearly, there is no factor common to every term. However, it is clear that 7 is a common factor of the first two terms and b is a common factor of the last two terms. So, the expression can be grouped into two pairs of two terms as shown. c.azzopardi.smc@gmail.com 9
3. The six terms don t have a common factor, but, taking them two at a time, you can pull out the factors Factoring by grouping, you get the following: The three new terms have a common factor of (x 2), so the factorization becomes Consolidation: Factorise the following completely:- 1. 6x + 9 + 2ax + 3a c.azzopardi.smc@gmail.com 10
2. x 2 6x + 5x 30 3. 5x + 10y ax 2ay 4. a 2 2a ax + 2x Support Exercise Pg 111 Exercise 8D Nos 1 2 Section 2.4 Factorising a Trinomial of the form of x 2 + bx + c Expanding (x + 4)(x + 2) gives x 2 + 2x + 4x + 8 x 2 + 6x + 8 Since factorization is the opposite of expanding the factorization of the expression x 2 + 6x + 8 gives (x + 4)(x + 2) c.azzopardi.smc@gmail.com 11
Sometimes it is easy to put a quadratic expression back into its brackets, other times it seems hard. However, there are some simple rules that will help you to factorise. The expression inside each set of brackets will start with an x, and the signs in the quadratic expression show which signs to put after the xs. When the second sign in the expression is a plus, the signs in both sets of brackets are the same as the first sign. x 2 + ax + b = (x +?)(x +?) x 2 ax + b = (x -?)(x -?) Since everything is positive. Since negative negative = positive Next, look at the last number, b, in the expression. When multiplied together, the two numbers in the brackets must give b. Finally, look at the coefficient of x, which is a. The sum of the two numbers in the brackets will give a. Example 1. Factorise x 2 + 5x + 6 Because of the signs we know that the signs must be of the form (x +?)(x +?). Two numbers that have a product of 6 and a sum of 5 are 3 and 2. Therefore, (x + 2)(x + 3) 2. Factorise x 2 9x + 20 Because of the signs the brackets must be of the form (x-?)(x-?) Two numbers that have a product which gives 20 and a sum of 9 are 4 and 5. Therefore, (x 4)(x 5) 3. Factorise x 2 7x + 10 Because of the signs the brackets must be of the form (x -?)(x -?) Two numbers that have a product which gives 10 and a sum of -7 are -5 and -2. Therefore, (x 5)(x 2) c.azzopardi.smc@gmail.com 12
Consolidation: Factorise the following expressions:- 1. x 2 + 5x + 6 2. k 2 + 10k + 24 3. w 2 + 11w + 18 4. t 2 5t + 6 5. y 2 16y + 48 6. y 2 + 6y + 8 7. x 2 + 16y + 39 c.azzopardi.smc@gmail.com 13
8. x 2 11x + 30 9. x 2 9x + 14 10. x 2 + 15x + 56 Support Exercise Pg 113 Exercise 8E No 2 (a g, m o) Section 2.5 Factorising a Trinomial of the form of x 2 + bx c Expanding (x 3)(x + 2) gives x 2 + 2x 3x 6 x 2 x 6 Since factorization is the opposite of expanding the factorization of the expression x 2 x 6 gives (x 3)(x + 2) When the second sign is a minus, the signs in the brackets are different. x 2 + ax b = (x +?)(x -?) Since positive negative = negative x 2 ax b = (x +?)(x -?) The larger factor will have the minus sign before it. Next, look at the last number, b, in the expression. When multiplied together, the two numbers in the brackets must give b. Finally, look at the coefficient of x, which is a. The sum of the two numbers in the brackets will give a. c.azzopardi.smc@gmail.com 14
1. Factorise x 2 x 6 Because of the signs we know that the signs must be of the form (x +?)(x-?). Two numbers that have a product of -6 and a sum of -1 are 3 and 2. The larger factor of these two factors is 3, therefore the minus must go with it. Therefore, (x + 2)(x 3) 2. Factorise x 2 + 3x 18 Because of the signs we know that the signs must be of the form (x +?)(x-?). Two numbers that have a product of -18 and a sum of 3 are 6 and 3. The larger factor of these two factors is 6, therefore the plus must go with it. Therefore, (x + 6)(x 3) Consolidation: Factorise the following expressions:- 1. y 2 + 5y 6 2. m 2 4m 12 3. h 2 h 72 c.azzopardi.smc@gmail.com 15
4. x 2 + 4x 21 5. x 2 4x 12 6. r 2 12r 28 7. x 2 + 2x 24 8. x 2 x 20 9. x 2-4x 21 10. h 2 + h - 72 Support Exercise Pg 113 Exercise 8E No 2 (h l, p, q) c.azzopardi.smc@gmail.com 16
Section 2.6 Factorising Mixed Examples Mixed Consolidation Examples 1. x 2-10x + 9 2. x 2 + x 12 3. x 2 6x 16 4. x 2 5x 14 5. x 2 x 2 6. x 2 12x + 20 c.azzopardi.smc@gmail.com 17
7. x 2 14x + 24 8. x 2 + 6x + 8 9. x 2 9x + 20 10. x 2 + 4x + 3 Support Exercise Handout Section 2.7 : Factorising ax 2 + bx + c We can adapt the method for factorizing x 2 + ax + b to take into account the factors of the coefficient of x 2. Example 1. Factorise 3x 2 + 8x + 4 First, note that both signs are positive. So the signs in the brackets must be (?x +?)(?x +?) As 2 has only 3 1 as factors, the brackets must be (3x +?)(x +?) c.azzopardi.smc@gmail.com 18
Next, notes that the factors of 4 are 4 1 and 2 2 Now find which pair of factors of 4 combined with the factors 3 give 8 3 4 2 1 1 2 You can see that the combination 3 2 and 1 2 adds up to 8 So the complete factorization becomes (3x + 2)(x + 2) 2. Factorise 6x 2 7x 10 Note that both signs are negative. So the signs in the brackets must be (?x +?)(?x -?) As 6 has 6 1 and 3 2 as fctors, the brackets could be (6x ±?)(x ±?) or (3x ±?)(2x ±?) Note that the factors of 10 are 5 2 and 10 1 Now find which pair of factors of 10 combined with the factors of 6 give 7. 3 6 ±1 ±2 2 1 ±10 ±5 You can see that the combination 6-2 and 1 5 adds up to -7. So, the complete factorization becomes (6x + 5)(x 2) c.azzopardi.smc@gmail.com 19
Consolidation: Factorise the following:- 1. 2x 2 + 5x + 2 2. 7x 2 + 8x + 1 3. 4x 2 + 3x 7 4. 24t 2 + 19t + 2 Support Exercise Pg 458 Exercise 28A No 1 26 Harder Trinomial Factorisation Handout Section 2.8 Factorisation of Harder Trinomials ax2 +bx + c It is not always possible to have a positive x 2 in the trinomial which we will be factorizing. In order to factorise polynomials with a negative x 2 we must follow the following steps. c.azzopardi.smc@gmail.com 20
Example 1 Factorise x 2 + 5x 6 Factorise by making the leading term POSITIVE. We do this by taking out a -1. [Remember to change the signs throughout the trinomial].this will give: -x 2 + 5x 6 = -1(x 2 5x + 6) = - (x 2 5x + 6) Factorise the bracket normally (Remember not to forget the minus sign outside the brackets) - (x 2 5x + 6) = - (x 3)(x 2) Once the bracket is factorised you may multiply the -1 with the first bracket - (x 3)(x 2) = (-x 3)(x 2) Consolidation 1. x 2 2x + 3 2. x 2 +x + 6 3. 2x 2 5x + 3 4. x 2 + x + 6 c.azzopardi.smc@gmail.com 21
5. m 2 10m 16 6. -6x 2 x + 7 Support Exercise Harder Trinomial Factorisation Handout Section 2.9 Factorising a Difference of Two Squares In Section 2.1 we multiplied out, for example (a + b)(a b) and obtained a 2 b 2. This type of quadratic expression, with only two terms, both of which are perfect squares separated by a minus sign, is called the difference of two squares. The following are examples of differences of two squares. x 2 9 x 2 25 x 2 4 x 2 100 There are three conditions that must be met for difference of two squares to work. There must be two terms They must be separated by a minus sign Each term must be a perfect square, say x 2 and n 2 When these three conditions are met the factorization is: x 2 n 2 = (x + n)(x n) c.azzopardi.smc@gmail.com 22
Example 1. Factorise x 2 36 Recognise the difference of two squares x 2 and 6 2 So it factorises to (x + 6)(x 6) To check your answer, expand the brackets once again. 2. Factorise 9x 2 169 Recognise the difference of two squares (3x) 2 and 13 2 So it factorises to (3x + 13)(3x 13) To check your answer, expand the brackets once again. Consolidation: Factorise the following:- 1. x 2 9 2. m 2 16 3. 9 x 2 4. x 2 64 5. t 2 81 c.azzopardi.smc@gmail.com 23
6. x 2 y 2 7. 9x 2 1 8. 4x 2 9y 2 9. 16y 2 25x 2 Support Exercise Pg 115 Exercise 8F Nos 1 4 Section 2.10 : Simplifying Algebraic Fractions (Rational Expressions) Algebraic expressions in the form of fractions are called Rational Expressions. Each of these rational expressions can be simplified by factorizing the numerator and denominator and then cancelling any expression which is common. For this section we must keep in mind all the factorizing methods which we have learnt till now. The following rules are used to work out the value of fractions: Multiplication Division Note that a, b, c and d can be numbers, other letters or algebraic expressions. Remember: c.azzopardi.smc@gmail.com 24
use brackets, if necessary factorise if you can cancel if you can Example 1. [We just cancel out top and bottom] 2. [(x 3) is common in the numerator and denominator and therefore we can cancel ] 3. Simplify fully 2x 2 + 4x = 2x(x + 2) x 2 4 = (x + 2)(x 2) [Factorise the numerator] [Factorise the denominator with difference of two squares] [Write as a fully factorised term] = [Cancel the common factor (x + 2)] [ is usually written as It is not possible to simplify any further.] 4. Simplify fully 3x+ 3 = 3(x + 1) [Factorise the numerator] x 2 + 3x + 2 = (x + 2)(x + 1) [Factorise the denominator] c.azzopardi.smc@gmail.com 25
Consolidation: Simplify fully:- 1. 2. 3. c.azzopardi.smc@gmail.com 26
Support Exercise Pg 460 Exercise 28B No 1 11 Section 2.11 : Simplifying Rational Expressions Example 1. Simplify fully x 2 9 = (x + 3)(x 3) x 2 2x 3 = (x 3)(x + 1) [Factorise the numerator] [Factorise the denominator] 2. Simplify fully 4 x 2 = (2 + x)(2 x) [Factorise the numerator] x 2 3x + 2 = (x 2)(x 1) [Factorise the denominator] [(x 2) = -1 (2 x)] c.azzopardi.smc@gmail.com 27
Consolidation: Simplify fully:- 1. 2. 3. c.azzopardi.smc@gmail.com 28
4. Support Exercise Pg 460 Exercise 28B No 12 25 Section 2.12 Adding and Subtracting Rational Expressions The following rules are used to work out the value of fractions: Addition Subtraction Example 1. Simplify [Find the LCM by multiplying the denominators and arrange the numerators accordingly] c.azzopardi.smc@gmail.com 29
2. Simplify [Find LCM and arrange numerator] [Take out the common if possible and cancel] Consolidation: Simplify the following:- 1. 2. 3. c.azzopardi.smc@gmail.com 30
4. Example 1. Write as a single fraction as simply as possible. To find the LCM we have to multiply the denominator Expand the numerator Collect like terms 2. Write as a single fraction in its simplest form First factorise all the denominators where it is possible c.azzopardi.smc@gmail.com 31
The LCM is x(x+2) (x+2) Since we now have the same denominator we just have to subtract the numerators Cancel if possible 3. Simplify Factorise the denominators To find the LCM we need a common factor for the number (15) and we can notice that (x+2) is in each fraction. LCM = 15(x + 2) We must arrange each fraction with denominator 15(x + 2) c.azzopardi.smc@gmail.com 32
Since the denominators are the same just combine the numerators Cancel top and bottom by 3 Consolidation: Simplify the following 1. 2. c.azzopardi.smc@gmail.com 33
3. 4. Support Exercise Pg 463 Exercise 28C No 1-20 c.azzopardi.smc@gmail.com 34