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College Algebra Sixth Edition James Stewart  Lothar Redlin  Saleem Watson

College Algebra Sixth Edition James Stewart  Lothar Redlin  Saleem Watson. Equations and Inequalities. 1. SOLVING QUADRATIC EQUATIONS. 1.6. Linear Equations vs. Quadratic Equations. Linear equations are first-degree equations, such as: 2 x + 1 = 5 or 4 – 3 x = 2

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College Algebra Sixth Edition James Stewart  Lothar Redlin  Saleem Watson

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  1. College Algebra Sixth Edition James StewartLothar RedlinSaleem Watson

  2. Equations and Inequalities 1

  3. SOLVING QUADRATIC EQUATIONS 1.6

  4. Linear Equations vs. Quadratic Equations Linear equations are first-degree equations, such as: 2x + 1 = 5 or 4 – 3x = 2 Quadratic equations are second-degree equations, such as: x2 + 2x – 3 = 0 or 2x2 + 3 = 5x

  5. Quadratic Equation—Definition A quadratic equation is an equation of the form ax2 + bx + c = 0 where a, b, and c are real numbers with a ≠ 0.

  6. Solving Quadratic Equations by Factoring

  7. Solving Quadratic Equations Some quadratic equations can be solved by factoring and using the following basic property of real numbers.

  8. Zero-Product Property AB = 0 if and only if A = 0 or B = 0 • This means that, if we can factor the LHS of a quadratic (or other) equation, then we can solve it by setting each factor equal to 0 in turn. • This method works only when the RHS is 0.

  9. E.g. 1—Solving a Quadratic Equation by Factoring Solve the equation x2 + 5x = 24 • We must first rewrite the equation so that the RHS is 0.

  10. E.g. 1—Solving a Quadratic Equation by Factoring x2 + 5x = 24 x2 + 5x – 24 = 0 (Subtract 24) (x – 3)(x + 8) = 0 (Factor) x – 3 = 0 or x + 8 = 0 (Zero-Product Property) x = 3 x = –8 (Solve)

  11. Solving a Quadratic Equation by Factoring Do you see why one side of the equation must be 0 in Example 1? • Factoring the equation as x(x + 5) = 24 does not help us find the solutions. • 24 can be factored in infinitely many ways, such as 6 . 4, ½ . 48, (–2/5) . (–60), and so on.

  12. Solving Quadratic Equations by Completing the Square

  13. Solving Simple Quadratics As we saw in Section P.8, Example 5(b), if a quadratic equation is of the form (x± a)2 = c, we can solve it by taking the square root of each side. • In an equation of this form, the LHS is a perfect square: the square of a linear expression in x.

  14. Completing the Square So, if a quadratic equation does not factor readily, we can solve it using the technique of completing the square.

  15. Completing the Square To make x2 + bx a perfect square, add , the square of half the coefficient of x. This gives the perfect square

  16. Completing the Square To compete the square, we add a constant to an expression to make it a perfect square. • For example, to makex2 + 6xa perfect square, we must add (6/2)2 = 9. Thenx2 + 6x + 9 = (x + 3)2is a perfect square.

  17. Completing the Square The table gives some more examples of completing the square.

  18. E.g. Solving Quadratic Equations by Completing the Square Solve each equation. • x2 – 8x + 13 = 0 • 3x2 – 12x + 6 = 0

  19. Example (a) E.g. 2—Completing the Square x2 – 8x + 13 = 0 x2 – 8x = –13 (Subtract 13) x2 – 8x + 16 = –13 + 16(Complete the square) (x – 4)2 = 3 (Perfect square) x – 4 = ± (Take square root) x = 4 ± (Add 4)

  20. Example (b) E.g. 2—Completing the Square First, we subtract 6 from each side. Then, we factor the coefficient of x2 (the 3) from the left side. • This puts the equation in the correct form for completing the square.

  21. E.g. 2—Completing the Square 3x2 – 12x + 6 = 0 3x2 – 12x = –6 (Subtract 6) 3(x2 – 4x) = –6 (Factor 3 from LHS)

  22. E.g. 2—Completing the Square Now, we complete the square by adding (–2)2 = 4 inside the parentheses. • Since everything inside the parentheses is multiplied by 3, this means that we are actually adding 3 . 4 = 12 to the left side of the equation. • Thus, we must add 12 to the right side as well.

  23. E.g. 2—Completing the Square 3(x2– 4x +4) = –6 + 3 .4(Complete the square) 3(x – 2)2 = 6 (Perfect square) (x – 2)2 = 2 (Divide by 3) (Take square root) (Add 2)

  24. The Quadratic Formula

  25. Deriving a Formula for the Roots We can use the technique of completing the square to derive a formula for the roots of the general quadratic equation ax2 + bx + c = 0

  26. The Quadratic Formula The roots of the quadratic equation ax2 + bx +c = 0 where a ≠ 0, are:

  27. The Quadratic Formula—Proof First, we divide each side of the equation by a and move the constant to the right side, giving:

  28. The Quadratic Formula—Proof We now complete the square by adding (b/2a)2 to each side of the equation.

  29. The Quadratic Formula The quadratic formula could be used to solve the equations in Examples 1 and 2. • You should carry out the details of these calculations.

  30. E.g. 3—Using the Quadratic Formula Find all solutions of each equation. • 3x2 – 5x – 1 = 0 • 4x2 + 12x + 9 = 0 • x2 + 2x + 2 = 0

  31. Example (a) E.g. 3—Using Quadratic Formula In 3x2 – 5x – 1 = 0, a = 3 b = –5 c = –1 By the quadratic formula,

  32. Example (a) E.g. 3—Using Quadratic Formula If approximations are desired, we can use a calculator to obtain:

  33. Example (b) E.g. 3—Using Quadratic Formula Using the quadratic formula with a = 4, b = 12, and c = 9 gives: • This equation has only one solution, x = –3/2.

  34. Example (c) E.g. 3—Using Quadratic Formula Using the quadratic formula with a = 1, b = 2, and c = 2 gives: • Since the square of a real number is nonnegative, is undefined in the real number system. • The equation has no real solution.

  35. The Discriminant

  36. Discriminant The quantity b2 – 4ac that appears under the square root sign in the Quadratic Formula is called the discriminant of the equation ax2 + bx + c = 0. • It is given the symbol D.

  37. D < 0 If D < 0, then is undefined. • The quadratic equation has no real solution—as in Example 3(c).

  38. D = 0 and D > 0 If D = 0, then the equation has only one real solution—as in Example 3(b). Finally, if D > 0, then the equation has two distinct real solutions—as in Example 3(a).

  39. Discriminant The following box summarizes these observations.

  40. E.g. 4—Using the Discriminant Use the discriminant to determine how many real solutions each equation has. • x2 + 4x – 1 = 0 • 4x2 – 12x + 9 = 0 • 1/3x2 – 2x + 4 = 0

  41. Example (a) E.g. 4—Using the Discriminant x2 + 4x – 1 = 0 The discriminant is: D = 42 – 4(1)(–1) = 20 > 0 • So, the equation has two distinct real solutions.

  42. Example (b) E.g. 4—Using the Discriminant 4x2 – 12x + 9 = 0 The discriminant is: D = (–12)2 – 4 . 4 . 9 = 0 • So, the equation has exactly one real solution.

  43. Example (c) E.g. 4—Using the Discriminant 1/3x2 – 2x + 4 = 0 The discriminant is: D = (–2)2 – 4(1/3)4 = –4/3 < 0 • So, the equation has no real solution.

  44. Modeling with Quadratic Equations

  45. Quadratic Equations in Real Life Let’s consider a real-life situation that can be modeled by a quadratic equation. • The principles discussed in Section 1.5 for setting up equations as models are useful here as well.

  46. E.g. 6—Dimensions of a Building Lot A rectangular building lot is 8 ft longer than it is wide and has an area of 2900 ft2. • Find the dimensions of the lot.

  47. E.g. 6—Dimensions of a Building Lot We are asked to find the width and length of the lot. • So, let: w = width of lot

  48. E.g. 6—Dimensions of a Building Lot Then, we translate the information in the problem into the language of algebra.

  49. E.g. 6—Dimensions of a Building Lot Now, we set up the model. Width of Lot . Length of Lot = Area of Lot

  50. E.g. 6—Dimensions of a Building Lot w(w + 8) = 2900 w2 + 8w = 2900 (Expand) w2 + 8w – 2900 = 0 (w – 50)(w + 58) = 0 (Factor) w = 50 or w = –58 (Zero-Product Property)

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