1 / 60

Polynomial and Rational Functions

Polynomial and Rational Functions. Aim #2.1 What are complex numbers?. The imaginary unit I is defined as. Complex numbers and Imaginary Numbers. The set of all numbers in the form of a + bi , with real numbers a and b and i , the imaginary unit, is called the set of

jerrymaxwell
Download Presentation

Polynomial and Rational Functions

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Polynomial and Rational Functions

  2. Aim #2.1 What are complex numbers? • The imaginary unit I is defined as

  3. Complex numbers and Imaginary Numbers • The set of all numbers in the form of a + bi, with real numbers a and b and i, the imaginary unit, is called the set of complex numbers. • An imaginary number in the form of bi is called a pure imaginary number. • Example: -4 + 6i, 0+ 2i= 2i

  4. A complex number is said to be simplified if its in the form of a + bi. • If b contain a radical express i before the radical.

  5. Equality of Complex numbers: a + bi= c + di if and only if a = c and b = d

  6. (5 – 11i) + (7 + 4i) Steps: Add or subtract the real parts Add or subtract the imaginary parts Express final answer as a complex number Operations with Complex Numbers

  7. (-5 + i) – (-11 – 6 i) Steps: Add or subtract the real parts Add or subtract the imaginary parts Express final answer as a complex number Operations with Complex Numbers

  8. 4i(3- 5i) Distribute 4i throughout the parenthesis Multiply Replace i2 with -1. Simplify Multiplying Complex Numbers

  9. (7 - 3i)(-2- 5i) Use the Foil Method or Vertical Method to multiply Replace i2 with -1 Simplify Multiplying Complex Numbers

  10. What are Conjugates? • The complex conjugate of the numbera + biisa – bi and vice versa. • When you multiply a complex number by its conjugate you get a real number.

  11. Divide and express the result in standard form. Multiply the numerator and denominator by the denominators conjugate. Use FOIL (or the Vertical Method) Replace i2 with -1 Simplify Express final answer in standard form. Using Complex Conjugates

  12. Roots of Negative Numbers

  13. Roots of Negative Numbers • Perform the indicated operation.

  14. Summary: Answer in complete sentences. • What is i? • Explain how to add or subtract complex numbers. • What is the conjugate of a complex number? • Explain how to divide complex numbers and provide an example.

  15. Aim #2.2: What are some properties of quadratic functions? • The Standard Form of Quadratic Function:

  16. General Form of a Quadratic: • f (x)= ax2 + bx + c • To find the vertex using this form you need the axis of symmetry:

  17. Graphing a Quadratic Function • Identify which way the parabola will open • Identify the vertex • Find the y –intercept by evaluating f(0). • Find the x-intercepts. • Then graph.

  18. Converting from General to Standard Form • Convert the function: • Y = x2 + 4x – 1 • Steps:

  19. Practice: • Convert to standard form. Y = 3x2 + 6 x + 7

  20. Summary:Answer in complete sentences. 3- List three things you learned about quadratic functions. 2- List 2 ways you can apply this to real world. 1- Write one question that you may still have on this topic.

  21. Aim #2.3: How do we identify polynomial functions and their graphs? • Examples and Non examples:

  22. Definition of a Polynomial Function

  23. Smooth, Continuous Graphs • Polynomial functions of degree 2 or higher have graphs that are smooth and continuous.

  24. Use the leading coefficient test to determine the end behavior. f (x)= x3 + 3x2 – x - 3 End behavior is how we describe a graph to the far left or far right. Using the Test: The leading coefficient is 1. The exponent is odd Odd-degree have graphs with opposite behavior at each end. Leading Coefficient Test

  25. Leading Coefficient Test • Odd – degree; positive leading coefficient • Graphs falls left and increases right • Odd – degree; negative leading coefficient • Graph rises left and falls right

  26. Use the leading coefficient test to determine the end behavior. f (x)= x4 – 4x2 Even degree; positive leading coefficient Rises left and rises right Even degree; negative leading coefficient Falls left and falls right Guided Practice:

  27. Using the Leading Coefficient Test • Use the leading coefficient test to determine the end behavior of the graph of: • f (x) = -4x3 ( x -1)2 (x + 5)

  28. Zeros of Polynomial Functions • Find all the zeros: f (x)= x3 + 3x2 –x -3

  29. Practice: • Find all the zeros: f (x)= x3 + 2x2 –4x -8

  30. Find all the zeros: f (x)= - x4 + 4x3 – 4x2 Steps: Set f (x) = 0 Multiply both sides by -1. Factor the GCF. Factor completely. Solve for x. Finding Zeros of a Polynomial Function

  31. Multiplicities of Zero

  32. If ris a zero with even multiplicity, then the graph touches the x-axis and turns around at r. Multiplicity and X-intercepts

  33. Multiplicity and X-intercepts • If ris a zero with odd multiplicity, then the graph crosses the x-axis at r. • Note: Regardless of multiplicity graphs tend to flatten out near the zeros with multiplicity greater than one.

  34. Finding Zeros and their Multiplicities • Find the zeros of f (x)= ½ (x + 1) (2x – 3)2 and give the multiplicity of each zero. • State whether the graph crosses the x-axis or touches the x-axis and turns around at each zero. • Steps: 1. Set f (x)= 0 and set each variable factor to 0.

  35. Aim # 2.4 How do we divide polynomials?

  36. Guided Practice:

  37. The Remainder Theorem

  38. The Factor Theorem

  39. Practice:

  40. Summary:Answer in complete sentences.

  41. Aim #2.5: How do we find the zeros of a polynomial function? • Rational Zero Theorem provides us with a tool we can use to make a list of all possible rational zeros of a polynomial function.

  42. Theorem states:

More Related