Presentation is loading. Please wait.

Presentation is loading. Please wait.

Review of Factoring Methods In this slideshow you will see examples of: 1.Factor GCF  for any # terms 2.Difference of Squares  binomials 3.Sum or Difference.

Published byElfreda Watts Modified over 9 years ago

Similar presentations

Presentation on theme: "Review of Factoring Methods In this slideshow you will see examples of: 1.Factor GCF  for any # terms 2.Difference of Squares  binomials 3.Sum or Difference."— Presentation transcript:

1 Review of Factoring Methods In this slideshow you will see examples of: 1.Factor GCF  for any # terms 2.Difference of Squares  binomials 3.Sum or Difference of Cubes  binomials 4.PST (Perfect Square Trinomial)  trinomials 5.Reverse of FOIL  trinomials 6.Factor by Grouping  usually for 4 or more terms

2 Example 1: GCF FIRST STEP for every expression: factor the GCF! 5x 3 – 10x 2 – 5x

3 Example 1: GCF FIRST STEP for every expression: factor the GCF! 5x 3 – 10x 2 – 5x 5x(x 2 – 2x – 1)

4 Example 2: GCF 3(x + 1) 3 – 6(x + 1) 2 Hint: Remember that a “glob” can be part of your GCF. Do you see a parenthetical expression repeated here?

5 Example 2: GCF 3(x + 1) 3 – 6(x + 1) 2 3(x + 1) 2 [ ] this is the GCF

6 Example 2: GCF 3(x + 1) 3 – 6(x + 1) 2 3(x + 1) 2 [ (x+1) -2 ] Left-over factors from: 1 st term 2 nd term

7 Example 2: GCF 3(x + 1) 3 – 6(x + 1) 2 3(x + 1) 2 [ (x+1) -2 ] 3(x + 1) 2 Combine like terms: +1 -2 (x – 1)

8 Example 3: Difference of Squares 75x 4 – 108y 2 GCF first! 3(25x 4 – 36y 2 ) 3(5x 2 – 6y) (5x 2 + 6y) Recall these binomials are called conjugates.

9 IMPORTANT! Remember that the difference of squares factors into conjugates... However, the SUM of squares is PRIME – cannot be factored! a 2 + b 2  PRIME a 2 – b 2  (a + b)(a – b)

10 Example 4: Sum/Difference of Cubes a 3 - b 3

11 ( ) Example 4: Sum/Difference of Cubes

12 a 3 - b 3 (a - b) ( ) Cube roots w/ original sign in the middle Example 4: Sum/Difference of Cubes

13 a 3 - b 3 (a - b) (a 2 + b 2 ) Squares of those cube roots. Note that squares will always be positive.

14 Example 4: Sum/Difference of Cubes a 3 - b 3 (a - b) (a 2 + ab + b 2 ) The opposite of the product of the cube roots

15 p 3 - 125 (p - 5) Cube roots of each Squares of those cube roots & with same sign opp of product of roots in middle Example 5: Sum/Difference of Cubes + 5p (p 2 + 25)

16 (4x 2 + 9y 2 ) 8x 3 + 27y 3 (2x +3y) Cube roots of each Squares of those cube roots & with same sign opp of product of roots in middle Example 5: Sum/Difference of Cubes – 6xy

17 Example 6: Difference of Cubes m 6 – 125n 3 (m 2 – 5n) Cube roots of each Squares of those cube roots & with same sign opp of product of roots in middle (m 4 + 25n 2 )+ 5m 2 n

18 Example 7: Special Case * 1 st step: Diff of Squares * 2 nd step: Sum/Diff of Cubes x 6 – 64y 6 ( ) ( )( )

19 Example 7: Special Case * 1 st step: Diff of Squares * 2 nd step: Sum/Diff of Cubes x 6 – 64y 6 (x 3 – 8y 3 ) (x 3 + 8y 3 ) ( )( )

20 Example 7: Special Case * 1 st step: Diff of Squares * 2 nd step: Sum/Diff of Cubes x 6 – 64y 6 (x 3 – 8y 3 ) (x 3 + 8y 3 ) (x–2y)(x 2 +2xy+4y 2 ) (x+2y)(x 2 -2xy+4y 2 )

21 Example 8: PST 9x 2 – 30x + 25 ( ) 2 Recall the PST test: Are the1st & 3rd terms squares? Is the middle term twice the product of their square roots?

22 Example 8: PST 9x 2 – 30x + 25 (3x – 5) 2

23 Example 9: Reverse FOIL (Trial & Error) 6x 2 – 17x + 12 ( ) 3x – 42x – 3

24 Reverse FOIL (Trial & Error) Hint: don’t forget to read the “signs” ax 2 + bx + c  ( + )( + ) ax 2 – bx + c  ( – )( – ) ax 2 + bx – c  ( + )( – ) positive product has larger value ax 2 – bx – c  ( + )( – ) negative product has larger value

25 Special Case 10: Some quartics can be factored like quadratics (x 4  x 2 ● x 2 ) x 4 – 5x 2 – 36 ( ) x 2 – 9x 2 + 4 But, you aren’t done yet! Do you see why? (x + 3)(x – 3)(x 2 + 4) Now you’re done!

26 Example 11: Factor by Grouping (4 or more terms) a(x – 7) + b(x – 7) (x – 7) (a + b) Note that this is a BINOMIAL – only two terms here Do you see that (x – 7) is a common glob or GCF? To factor by grouping, your goal will be to rewrite a statement so it will have such factorable globs! Glob is the GCF Left-over factors

27 Example 11: Factor by Grouping (4 or more terms) x 3 – 2x 2 + ax – 2a Can you take a GCF out of the first pair and a GCF out of the second pair? Will this leave a common GLOB as a GCF? (If not, rearrange the order of terms & try a different plan.) We will call this “Grouping 2 X 2”

28 Example 11: Factor by Grouping – 2 X 2 x 3 – 2x 2 + ax – 2a x 2 [x – 2 ] + a [x – 2] [x – 2 ] Glob is a GCF “Left-Over”Factors (x 2 + a)

29 Summary: Factor by Grouping 2 X 2 x 3 – 2x 2 + ax – 2a Look for two small [x 3 – 2x 2 ] +[ ax – 2a] factorable groups! x 2 [x – 2] + a [x – 2] Check IF same leftover factor (glob)! [x – 2 ] (x 2 + a) Pull the final GCF out in front of the leftover factors.

30 Example 12: Factor by Grouping – 2 X 2 m 2 – n 2 + am + an [m – n] [m + n] + [m + n] Glob is a GCF “Left-Over”Factors ([m – n] + a) a [m + n]

31 Summary: Factor by Grouping – 2 X 2 m 2 – n 2 + am + an [m – n][m + n] + a[m + n] [m + n] ([m – n] + a) Look for two pairs of factorable terms – here the first pair are a difference of squares and the second pair have a GCF of “a” Pull the GCF out in front and then simply write the “left-over” factor from each term. Factoring each pair gave a binomial that has a GCF glob of “m + n”. Grouping is a premlinary step that MUST lead to a second factoring step. (If your grouping step leads to a dead-end, try re-ordering the terms with different groups. Hint: look for a GCF or PST.)

32 Example 13: Factor by Grouping 3 X 1 x 2 + 9 – 4y 2 + 6x Can you rearrange the terms to put the three terms of a PST first followed by the opposite of a perfect square? Then rewrite the PST into (glob) 2 factored form. Now factor this binomial using Difference of Squares We will call this “Grouping 3 X 1”

33 Example 13: Factor by Grouping 3 X 1 x 2 + 6x + 9 – 4y 2 [x 2 + 6x + 9 ] – [4y 2 ] Do you see this as a PST? Isn’t this also a Can you write it as (glob) 2 ? perfect square?

34 Example 12: Factor by Grouping 3 X 1 x 2 + 6x + 9 – 4y 2 [x 2 + 6x + 9 ] – [4y 2 ] (x + 3) 2 – 4y 2

35 Example 13: Factor by Grouping 3 X 1 x 2 + 6x + 9 – 4y 2 [x 2 + 6x + 9 ] – [4y 2 ] (x + 3) 2 – 4y 2 [(x + 3) + 2y] [(x + 3) – 2y]

36 Examples 14 & 15: Factor by Grouping a 2 – 10a – 49b 2 + 25 a 2 – 10a + 25 – 49b 2 [a 2 – 10a + 25 ] – [49b 2 ] (a – 5) 2 – [49b 2 ] [(a – 5) + 7b] [(a – 5) – 7b] ax – ay – bx + by a[x – y ] – b[x – y] [x – y][a – b]

37 Factoring is a basic SKILL for Precalc & Calculus, so PRACTICE until you are quick & confident! Look for a GCF first and then check for additional steps: 1.Factor GCF  for any # terms 2.Difference of Squares  binomials 3.Sum or Difference of Cubes  binomials 4.PST (Perfect Square Trinomial)  trinomials 5.Reverse of FOIL  trinomials 6.Factor by Grouping  usually for 4 or more terms

38 Factor each expression completely. Bring your written work and questions with you to class tomorrow! 1.4a 3 b – 36ab 3 2.2x 4 y – 12xy – 54y 3.4x 2 – 20x + 25 – 100y 2 4.3a + 3b – 5ac – 5bc 5.80m 3 n – 270n 4

Download ppt "Review of Factoring Methods In this slideshow you will see examples of: 1.Factor GCF  for any # terms 2.Difference of Squares  binomials 3.Sum or Difference."

Similar presentations

Follow these basic steps …. Factor out the GCF. Count how many terms and try the following tactics. Then, go to step 3.  2 terms -- difference of 2.

Follow these basic steps …. Factor out the GCF. Count how many terms and try the following tactics. Then, go to step 3.  2 terms -- difference of 2.
Factoring Polynomials

Factoring Polynomials
7.1 The Greatest Common Factor and Factoring by Grouping

7.1 The Greatest Common Factor and Factoring by Grouping
Factoring trinomials ax² + bx +c a = any number besides 1 and 0

Factoring trinomials ax² + bx +c a = any number besides 1 and 0
Factoring Trinomials of the form

Factoring Trinomials of the form
Factoring Polynomials. GCF. Factor by grouping. Factor a trinomial

Factoring Polynomials. GCF. Factor by grouping. Factor a trinomial
Factoring Polynomials Digital Lesson. Copyright © by Houghton Mifflin Company, Inc. All rights reserved. 2 Greatest Common Factor The simplest method.

Factoring Polynomials Digital Lesson. Copyright © by Houghton Mifflin Company, Inc. All rights reserved. 2 Greatest Common Factor The simplest method.
1. Copyright © 2007 Pearson Education, Inc. Publishing as Pearson Addison-Wesley Factoring CHAPTER 6.1Greatest Common Factor and Factoring by Grouping.

1. Copyright © 2007 Pearson Education, Inc. Publishing as Pearson Addison-Wesley Factoring CHAPTER 6.1Greatest Common Factor and Factoring by Grouping.
5.1 Factoring a monomial from a polynomial

5.1 Factoring a monomial from a polynomial
P.4 FACTORING (التحليل) Objectives: Greatest Common Factor

P.4 FACTORING (التحليل) Objectives: Greatest Common Factor
Factoring Decision Tree

Factoring Decision Tree
Any questions on the Section 5.6 homework?. Please CLOSE YOUR LAPTOPS, and turn off and put away your cell phones, and get out your note- taking materials.

Any questions on the Section 5.6 homework?. Please CLOSE YOUR LAPTOPS, and turn off and put away your cell phones, and get out your note- taking materials.
6 – 4: Factoring and Solving Polynomial Equations (Day 1)

6 – 4: Factoring and Solving Polynomial Equations (Day 1)
5.1 Factoring – the Greatest Common Factor

5.1 Factoring – the Greatest Common Factor
Factoring Polynomials

Factoring Polynomials
Copyright © 2011 Pearson Education, Inc. Publishing as Prentice Hall. Chapter 11 Factoring Polynomials.

Copyright © 2011 Pearson Education, Inc. Publishing as Prentice Hall. Chapter 11 Factoring Polynomials.
INTRODUCTION TO FACTORING POLYNOMIALS MSJC ~ San Jacinto Campus Math Center Workshop Series Janice Levasseur.

INTRODUCTION TO FACTORING POLYNOMIALS MSJC ~ San Jacinto Campus Math Center Workshop Series Janice Levasseur.
Section 5.4 Factoring FACTORING Greatest Common Factor,

Section 5.4 Factoring FACTORING Greatest Common Factor,
Review Factoring Techniques for the Final Exam

Review Factoring Techniques for the Final Exam
Factoring Polynomials

Factoring Polynomials

Similar presentations

Ads by Google