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Chabot Mathematics §5.4 Factor TriNomials Bruce Mayer, PE Licensed Electrical & Mechanical Engineer [email protected] Chabot College Mathematics 1 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Review § 5.3 MTH 55 Any QUESTIONS About • §5.3 → Factoring by GCF and/or Grouping Any QUESTIONS About HomeWork • §5.3 → HW-13 Chabot College Mathematics 2 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factor (+1)·x2 + bx + c Recall the FOIL method of multiplying two binomials: F O I L (x + 2)(x + 5) = x2 + 5x + 2x + 10 = x2 + Chabot College Mathematics 3 7x + 10 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factor (+1)·x2 + bx + c To factor x2 + 7x + 10, think of FOIL: The first term, x2, is the product of the First terms of two binomial factors, so the first term in each binomial must be x. The challenge is to find two numbers p and q such that p•q = c, and p+q = b x2 + 7x + 10 = (x + p)(x + q) = x2 + qx + px + pq Chabot College Mathematics 4 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factor (+1)·x2 + bx + c Need to find two numbers p & q such that x2 + 7x + 10 = (x + p)(x + q) = x2 + qx + px + pq Thus the numbers p and q must be selected so that their • PRODUCT is 10 • SUM is 7 The Factor Pairs for 10 [and their sums] • 1·10 [11]; (−1)·(−10) [−11]; 2·5 [7]; (−2)·(−5) [−7]; Chabot College Mathematics 5 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factor (+1)·x2 + bx + c In this case, Examination of the “c” term factor-pairs revealed the desired numbers p=2 & q=5 Thus the factorization for x2 + 7x + 10 (x + 2)(x + 5) or (x + 5)(x + 2). Note that the FACTORING Process converted an ADDITION-chain into a pure MULTIPLICATION-Chain Chabot College Mathematics 6 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example FOIL Factoring Multiplying binomials uses the FOIL method, Factoring uses the FOIL method backwards Product of x and x x2 . is F L Product of 5 and –7 is –35. Sum of the product of outer and inner terms O Chabot College Mathematics 7 I Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factor x2 + bx + c for Positive c When the constant term of a trinomial is positive, look for two numbers with the same sign. The sign is that of the middle term: x2 – 7x + 10 = (x – 2)(x – 5); x2 + 7x + 10 = (x + 2)(x + 5); Chabot College Mathematics 8 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor x2 + 7x + 12 SOLUTION: Think of FOIL in reverse: (x + )(x + ) We need a constant term that has a product of 12 and a SUM of 7. We list some pairs of numbers that multiply to 12 Chabot College Mathematics 9 Pairs of Sums of Factors of 12 Factors 1, 12 2, 6 3, 4 1, 12 2, 6 3, 4 13 8 7 13 8 7 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor x2 + 7x + 12 Since 3 4 = 12 and 3 + 4 = 7, the factorization of x2 + 7x + 12 is (x + 3)(x + 4). To check we simply multiply the two binomials. CHECK by FOIL: (x + 3)(x + 4) = x2 + 4x + 3x + 12 = x2 + 7x + 12 Chabot College Mathematics 10 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor y2 – 8y + 15 SOLUTION: Since the constant term is positive and the coefficient of the middle term is negative, we look for the factorization of 15 in which both factors are negative. Their SUM must be −8. Pairs of Factors of 15 Sums of Factors –1, –15 –3, –5 –16 –8 Chabot College Mathematics 11 Sum of −8 y2 − 8y + 15 = (y − 3)(y – 5) Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factor x2 + bx + c for Negative c When the constant term of a trinomial is negative, look for two numbers whose product is negative. One must be positive and the other negative: x2 – 4x – 21 = (x + 3)(x – 7); x2 + 4x – 21 = (x – 3)(x + 7). Select the two numbers so that the number with the LARGER absolute value has the SAME SIGN as b, the coefficient of the middle term Chabot College Mathematics 12 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor x2 – 5x – 24 SOLUTION: The constant term must be expressed as the product of negative & positive numbers. Since the sum of the two numbers must be negative, the negative number must have the greater absolute value. Chabot College Mathematics 13 Pairs of Factors of 24 Sums of Factors 1, 24 2, 12 3, 8 4, 6 6, 4 8, 3 23 10 5 2 2 5 x2 − 5x − 24 = (x + 3)(x – 8) Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor t2 – 32 + 4t SOLUTION: Rewrite the trinomial t2 + 4t − 32. We need one positive and one negative factor. The sum must be 4, so the positive factor must have the larger absolute value Chabot College Mathematics 14 Pairs of Factors of 32 Sums of Factors 1, 32 2, 16 4, 8 31 14 4 t2 + 4t − 32 = (t + 8)(t − 4) Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Two Variables Factor: a2 + ab − 30b2 SOLUTION We need the factors of a2 & 30b2 that when added equal ab. • Those factors are a, and −5b & 6b. a2 + ab − 30b2 = (a − 5b)(a + 6b) Chabot College Mathematics 15 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Prime Polynomials A polynomial that canNOT be factored is considered prime. • Example: x2 − x + 7 Often factoring requires two or more steps. Remember, when told to factor, we should factor completely. This means the final factorization should contain only prime polynomials. Chabot College Mathematics 16 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 2x3−24x2+72x SOLUTION Always look first for a common factor. In this case factor out 2x: 2x(x2 − 12x + 36) Since the constant term is positive and the coefficient of the middle term is negative, we look for the factorization of 36 in which both factors are negative. • Their SUM must be −12. Chabot College Mathematics 17 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 2x3–24x2+72x The factorization of (x2 – 12x + 36) is (x – 6)(x – 6) or (x – 6)2 The factorization of 2x3 – 24x2 + 72x is 2x(x – 6)2 or 2x(x – 6)(x – 6) Pairs of Factors of 36 Sums of Factors 1, 36 2, 18 3, 12 4, 9 6, 6 37 20 15 13 12 2x3 – 242x – 72x = 2x(x – 6 )(x – 6) Chabot College Mathematics 18 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt To Factor (+1)·x2 + bx + c 1. Distribute out Common Factors 2. Find a pair of factors that have c as their product and b as their sum. a) If c is positive, its factors will have the same sign as b. b) If c is negative, one factor will be positive and the other will be negative. Select the factors such that the factor with the larger absolute value has the same sign as b. 3. CHECK by MULTIPLYING Chabot College Mathematics 19 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factoring When: LeadCoeff ≠ 1 Factoring Trinomials of the Type ax2 + bx + c • Factoring with FOIL • The Grouping Method Chabot College Mathematics 20 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factor ax2+bx+c by FOIL Chabot College Mathematics 21 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 3x2 – 14x – 5 1. First, check for a common factor, or GCF for all Terms. There is none other than 1 or −1. 2. Find the First terms whose product is 3x2. The only possibilities are 3x and x: (3x + )(x + ) 3. Find the Last terms whose product is −5. Possibilities are (−5)(1) & (5)(−1) Important!: Since the First terms are not identical, we must also consider the above factors in reverse order: (1)(−5), & (−1)(5). Chabot College Mathematics 22 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 3x2 – 14x – 5 4. Knowing that the First and Last products will check, inspect the Outer and Inner products resulting from steps (2) and (3) Look for the combination in which the sum of the products is the middle term. (3x – 5)(x + 1) = 3x2 + 3x – 5x – 5 = 3x2 – 2x – 5 Wrong middle term (3x – 1)(x + 5) = 3x2 + 15x – x – 5 = 3x2 + 14x – 5 Wrong middle term close Chabot College Mathematics 23 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 3x2 – 14x – 5 4. Keep Trying the factors of −5. (3x + 5)(x – 1) = 3x2 – 3x + 5x – 5 = 3x2 + 2x – 5 Wrong middle term (3x + 1)(x – 5) = 3x2 – 15x + x – 5 = 3x2 – 14x – 5 CORRECT middle term! Thus 3x2 – 14x – 5 = (3x + 1)(x – 5) Chabot College Mathematics 24 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt LdCoeff ≠ 1 Factorization Notes Reversing the signs in the binomials reverses the sign of the middle term Organize your work so that you can keep track of which possibilities you have checked. Remember to include the largest common factor - if there is one - in the final factorization. ALWAYS CHECK by multiplying Chabot College Mathematics 25 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 14x + 5 – 3x2 SOLUTION: It is an important problem-solving strategy to find a way to make problems look like problems we already know how to solve. Rewrite the equation in descending order. 14x + 5 – 3x2 = – 3x2 + 14x + 5 Chabot College Mathematics 26 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 14x + 5 − 3x2 Starting with −3x2 + 14x + 5 Factor out the –1: −3x2 + 14x + 5 = −1(3x2 − 14x − 5) = −1(3x + 1)(x − 5) The factorization of 14x + 5 − 3x2 is −1(3x + 1)(x − 5). or (−3x − 1)(x − 5) or (3x + 1)(−x + 5) Chabot College Mathematics 27 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example 2Vars: 6x2 − xy − 12y2 SOLUTION: No common factors exist, we examine the first term, 6x2. There are two possibilities: (2x + )(3x + ) or (6x + )(x + ). The last term −12y2, has pairs of factors: 12y, −y 6y, −2y 4y, −3y and −12y, y −6y, 2y −4y, 3y as well as each pairing reversed. Chabot College Mathematics 28 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example 2Vars: 6x2 − xy − 12y2 SOLUTION: Some trials such as (2x – 6y)(3x + 2y) and (6x + 4y)(x – 3y), cannot be correct because (2x – 6y) and (6x + 4y) contain a common factor, 2. Trial Product (2x + 3y)(3x − 4y) 6x2 − 8xy + 9xy − 12y2 = 6x2 + xy − 12y2 Chabot College Mathematics 29 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example 2Vars: 6x2 − xy − 12y2 SOLUTION: the Trial (2x + 3y)(3x − 4y) incorrect, but only because of the sign of the middle term. To correctly factor, simply change the signs in the binomials. Trial Product (2x − 3y)(3x + 4y) 6x2 + 8xy − 9xy − 12y2 = 6x2 − xy − 12y2 The factorization: (2x − 3y)(3x + 4y) Chabot College Mathematics 30 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example 18m2 – 19mn – 12n2 SOLUTION There are no common factors. Factor the first term, 18m2 and get the following possibilities: 18mm, 9m2m, and 6m3m. Factor the last term, −12n2, which is negative. The possibilities are: (−12n)(n), (−n)(12n), (−2n)(6n), (6n)(−2n), (−4n)(3n) or (−3n)(4n) Chabot College Mathematics 31 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example 18m2 – 19mn – 12n2 Look for combinations of factors such that the sum of the outside and the inside products is the middle term, (−19mn). • (9m + n)(2m − 12n) = 18m2 − 106mn − 12n2 • (9m − 12n)(2m + n) = 18m2 − 15mn − 12n2 • (9m − 3n)(2m + 4n) = 18m2 + 30mn − 12n2 • (9m + 4n)(2m – 3n) = 18m2 − 19mn − 12n2 Thus ANS → (9m + 4n)(2m − 3n) Chabot College Mathematics 32 correct middle term Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factoring by Substitution Some times substituting a single varaible for a (complicated) expression reveals an easily factored PolyNomial Example factor p2q2 + 7pq + 6 SOLUTION Rewrite using Product-to-Power Exponent rule → (pq)2 + 7(pq) + 6 Now engage a substitution Chabot College Mathematics 33 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factoring by Substitution factor p2q2 + 7pq + 6 = (pq)2 + 7(pq) + 6 Now to engage a substitution LET u = pq Replace in the Expression pq with u u2 + 7u + 6 The Expression in u is easily FOIL-factored u2 + 7u + 6 = (u + 6)(u + 1) Chabot College Mathematics 34 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factoring by Substitution Now BACK Substitute u = pq (u)2 + 7 (u) + 6 = (u + 6)(u + 1) (pq)2 + 7(pq) + 6 = (pq + 6)(pq + 1) p2q2 + 7pq + 6 = (pq + 6)(pq + 1) Chabot College Mathematics 35 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt WhiteBoard Work Problems From §5.4 Exercise Set • 30, 44, 66, 82, 92 Shaded Area Equals 1 2 2 2 x 4 x 2 x x 2 A 8x 2x 2 x 4 2 Chabot College Mathematics 36 2 2 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt All Done for Today F.O.I.L. Factoring Chabot College Mathematics 37 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Chabot Mathematics Appendix r s r s r s 2 2 Bruce Mayer, PE Licensed Electrical & Mechanical Engineer [email protected] – Chabot College Mathematics 38 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Factoring ax2+bx+c by Grouping 1. Factor out the largest common factor, if one exists. 2. Multiply the leading coefficient a and the constant c; i.e., form the a•c product 3. Find a pair of factors of a•c whose sum is b. 4. Rewrite the middle term, bx, as a sum or difference using the factors found in step (3). 5. Factor by grouping. 6. Include any common factor from step (1) and check by multiplying. Chabot College Mathematics 39 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 4x2 – 5x – 6 SOLUTION 1. First, we note that there is no common factor (other than 1 or −1). 2. We multiply the leading coefficient, 4 and the constant, −6: (4)(−6) = −24. 3. We next look for the factorization of −24 in which the sum of the factors is the coefficient of the middle term, −5. Chabot College Mathematics 40 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 4x2 – 5x – 6 3. Pairs of Sums of Factors of -24 Factors 1, –24 –23 –1, 24 23 2, –12 –10 –2, 12 10 3, –8 –5 –3, 8 5 4, –6 –2 –4, 6 2 Chabot College Mathematics 41 We would normally stop listing pairs of factors once we have found the one we need Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 4x2 – 5x – 6 4. Next, we express the middle term as a sum or difference using the factors found in step (3): −5x = −8x + 3x. 5. We now factor by grouping as follows: 4x2 − 5x − 6 = [4x2 − 8x] + [3x − 6] = 4x(x − 2) + 3(x − 2) = (x − 2)(4x + 3) Chabot College Mathematics 42 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example Factor 4x2 – 5x – 6 6. CHECK by FOIL: (x − 2)(4x + 3) = 4x2 + 3x − 8x − 6 = 4x2 − 5x − 6 The factorization of 4x2 − 5x − 6 is (x − 2)(4x + 3). Chabot College Mathematics 43 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example: Factor 8x3 + 10x2 – 12x SOLUTION 1. Factor out the Greatest Common Factor (GCF), 2x: 8x3 + 10x2 − 12x = 2x(4x2 + 5x − 6) 2. To factor 4x2 + 5x − 6 by grouping, we multiply the leading coefficient, 4 and the constant term (−6): 4(−6) = −24. Chabot College Mathematics 44 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example: Factor 8x3 + 10x2 – 12x 3. next look for pairs of factors of −24 whose sum is 5. Pairs of Factors of −24 Sums of Factors 3, −8 −3, 8 −5 5 4. We then rewrite the 5x in 4x2 + 5x − 6 using: 5x = −3x + 8x Chabot College Mathematics 45 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Example: Factor 8x3 + 10x2 – 12x 5. Next, factor by grouping: 4x2 + 5x − 6 = [4x2 − 3x] + [8x − 6] = x(4x − 3) + 2(4x − 3) = (x + 2)(4x − 3) 6. The factorization of the original trinomial 8x3 + 10x2 − 12x is 2x(x + 2)(4x − 3) Chabot College Mathematics 46 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt Graph y = |x| 6 Make T-table x -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 Chabot College Mathematics 47 5 y = |x | 6 5 4 3 2 1 0 1 2 3 4 5 6 y 4 3 2 1 x 0 -6 -5 -4 -3 -2 -1 0 1 2 3 -1 -2 -3 -4 -5 file =XY_Plot_0211.xls -6 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt 4 5 6 y 5 4 3 2 1 x 0 -3 -2 -1 0 1 2 3 4 5 -1 -2 M55_§JBerland_Graphs_0806.xls -3 Chabot College Mathematics 48 Bruce Mayer, PE [email protected] • MTH55_Lec-22_sec_5-3_GCF-n-Grouping.ppt