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Unit 2 Polynomial and Rational Functions

Unit 2 Polynomial and Rational Functions. Do Now Given the following function, find. Unit 2 Lesson 1 2.1 Quadratic Functions 2.2 Polynomial Functions.

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Unit 2 Polynomial and Rational Functions

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  1. Unit 2Polynomial and Rational Functions

  2. Do NowGiven the following function, find

  3. Unit 2 Lesson 12.1 Quadratic Functions2.2 Polynomial Functions

  4. Lesson ObjectivesIn this lesson presentation, you will learn how to: define, sketch & analyze graphs of quadratic & polynomial functions.define and identify the vertex, minimum and maximum values of a quadratic& polynomial functions.use the LEADING COEFFICENT TEST to determine how a polynomial function rises or falls.identify the zeros of both of quadratic & polynomial functions.use the Intermediate Value Theorem to help identify the real zeros of a polynomial function.

  5. 2.1 Quadratic Functions a, b, and c are real numbers where a0 When graphed called a Parabola

  6. Axis of Symmetry – all parabolas are symmetric (line where it’s cut in half) Vertex – axis intersects the parabola

  7. If a is positive… If a is negative…opens up opens down Minimum: (0,0) Maximum: (0,0)Axis of Symmetry for both: x=0

  8. If a is positive…opens up If a is negative…opens downVertexis lowest point. Vertexis highest point.Axis of symmetry

  9. Base function or squaring function.How does each function change?1) Up 5 units2) Left 5 units3) Get’s skinny

  10. Summarize: How do they change?If c>0, then move up. If c<0, then move down.If (x+#), then move left. If (x-#), then move right.If “a” is integer, then get skinny.If “a” is fraction, then get wide.

  11. Practice Given the following functions, graph each on your graph paper and identify the following: a) Domain: b) Range: c) Decreasing on: d) Increasing on: e) Turn up or down:Example 1.Example 2.

  12. Practice Given the following function, identify the following:Domain:Range:Decreasing on:Increasing on:Turn up or down:

  13. Standard Form of a Quadratic Vertex is (h, k) and a0 Axis is the vertical line x = h If a < 0, then the parabola opens down If a > 0, then the parabola opens up

  14. Identify the vertex of a QuadraticGiven a functionWrite the function in Standard Form by completing the square to find the vertex.Example 1. *Factor out the 2 *b=4, add & subtract (4/2)2 =4 *Regroup terms *Write in Standard Form. The vertex is (-2,-3)

  15. Identify the Minimum & Maximum ValuesGiven a functionYou can find the minimum if a>0,You can find the maximum if a<0 Example: Given the following quadratic equation find coordinates of the relative minimum or maximum point.

  16. 2.2 Graphs of Polynomial Functions Features of Polynomial Functions: Continuous Smooth Curves NOT Features of Polynomial Functions: NOT Continuous NOT Smooth

  17. Functions with 1 degree are Linear.Functions with 2 degrees are Quadratic.Functions with 3rd or greater are Polynomial. Functions with an even degree will look like our quadratics. (e.g.) Functions with an odd degree will look like our cubic. (e.g.)

  18. A polynomial of the nthdegree has the form: n is a positive integer The greater the value of n the flatter the graph near (0,0)

  19. The Leading Coefficient Test A functions ability to rise or fall can be determined by the functions degree (even or odd) and by it’s leading coefficient.

  20. When n is odd: When When n is odd: When

  21. When n is even: When When n is even:When

  22. Independent Practice: Take a minute to see if you can develop four different polynomial functions that would behave as we just discussed. Write down your functions and check your work in you calculator. Practice Use the Leading Coefficient Test to determine the right and left side behavior of the function. Example 1. Example 2.

  23. Finding Zeros of Polynomial Functions Set the function equal to zero and factor. (e.g) Check on the graphing calculator.

  24. 2.3 Real Zeros of Polynomial FunctionsDisclaimer:There are many ways for us to determine the zeros of a polynomial function. Please be patient and as the lesson progresses through the various topics the math should become easier for you! Topics will include: *Long Division of Polynomials *Synthetic Division *Remainder & Factor Theorems *Rational Zero Test *Descartes's Rule of Signs

  25. Long Division of Polynomials Graph the function to identify a zero that is an integer. You can see that x=2 is a zero, as a result (x-2) is a factor of the polynomial. We will divide the entire function by (x-2).

  26. Divide! 1) Multiply: 2) Subtract. 3) Multiply: 4) Subtract. 5) Multiply: 6) Subtract.

  27. Now we know that: So we factor and solve for zero! We have three x-intercepts at:

  28. Synthetic Division (the shortcut to long division) We will use Synthetic Division to divide the following: Solve to get divisor: Leading coefficients (NOTE: zero because there is no x cubed. -3 1 0 -10 -2 4 -3 9 3 -3 1 -1 1 1 -3 Remainder: 1 1) Add terms in first column, and multiply the result by -3. 2) Repeat this process until the last column.

  29. -3 1 0 -10 -2 4 9 3 -3 -3 1 -1 1 1 -3 Quotient: Remainder: original problem = quotient + remainder

  30. Remainder & Factor Theorems The Remainder Theorem (the remainder from synthetic division): If a polynomial is divided by x-k, the remainder is . Practice 1. Use the Remainder Theorem to evaluate the given function at x = -2. Start by doing synthetic division!

  31. -2 3 8 5 -7 -2 -4 -6 2 3 1 -9 Remainder is -9, . (-2,-9) is a point on the graph of our polynomial. Check by substituting in -2 into our original function.

  32. Rational Zero Test If the polynomial has integer coefficients, every rational zero of f has the form: Rational Zero p: factor of constant term q: factor of leading coefficient

  33. Example 1.Find the rational zero(s) of the given function. The factors of 1 are +1 and -1 Therefore: Rational Zeros: +1 or -1 Test each possible zero algebraically. Since -1, and 3 are not zero, this polynomial does not have a rational zero.

  34. If the leading coefficient is not 1 our possible zeros will increase significantly. *We will use our graphing calculators to plot the zeros for these situations. If you would like to see a problem working out please reference pg.119 in your textbook. Practice. Using your graphing calculator find the rational zeros of the following function.

  35. Variation in sign: Two consecutive (nonzero) coefficients have opposite signs. Example:Do the given functions have a difference of signs? + to + + to + NO!!! + to + + to - + to - YES!!! - to +

  36. Descartes's Rule of Signs Let Be a polynomial with real coefficients and . 1. The number of positive real zeros of f is either equal to the number of variations in sign of f(x) or less than the number by an even integer. 2.The number of negative real zeros of f is either equal to the number of variations in sign of f(-x) or less than the number by an even integer.

  37. Example. Describe the possible real zeros of the given function. + to - + to + This polynomial has either two or no positive real zeros. - to + - to - - to + This one negative real zeros. - to -

  38. 2.4 The Imaginary Unit i If a and b are real numbers: a + bi is a complex number in standard form If b = 0, a +bi = a If b ≠ 0, a +bi is an imaginary number If b≠ 0, bi is a pure imaginary number.

  39. Addition & Subtraction with Complex Numbers Just like combining like terms in Algebra! Example1: Solve / Simplify. (5 - i) + (9 + 5i) Example2: Solve / Simplify. 10 + (3 + 6i) - (-2 + 2i)

  40. Multiplication with Complex Numbers Remember: Example1: Multiply. Example 2: Multiply. (3 + 2i)(5 + 4i)

  41. Complex Conjugates When two complex numbers are multiplied and their solution is a real number. (remember the difference of squares?) Example of Complex Conjugates: (5 + 2i)(5 – 2i)

  42. Find the complex conjugate for the following complex number and multiply. (7- 4i)

  43. Division with Complex Numbers Example1: Write the following quotient in standard form.

  44. 2.5 The Fundamental Theorem of Algebra The Fundamental Theorem of Algebra Iff(x) is a polynomial of degree n, where n > 0, the f has at least one zero in the complex number system.

  45. Linear Factorization Theorem Iff(x) is a polynomial of degree n where n > 0, f has precisely n linear factors. Where are complex numbers.

  46. Example 1. Using the Ft of A and LFT, prove that the given 3rd degree polynomial function does indeed have three exact zeros in the complex number system. Factor completely. Find your zeros.

  47. Conjugate Pairs (think: difference of squares) FACT: Complex zeros occur in conjugate pairs! (think about the last example!) If is a zero of a function, then the conjugate is also a zero.

  48. Example 2. Using you knowledge of the FTofA, LFT, and conjugate pairs find all of the zeros of the given function if 1 + 3i is a zero. If 1 +3i is a zero we know that 1 – 3i is a zero. If x = (1 + 3i), then x – (1 + 3i) is a factor. Multiply. Distribute. Multiply.

  49. Now, use long division to divide.

  50. Factor! Remember this… Please practice this following problems with you partner so that I can walk throughout the room and provide help and assistance as needed. Pg.141 #13, & 47 (use the answers in the back of the book for help!)

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