1 / 32

Rational Functions

Rational Functions. Lesson 2.6, page 326. Objectives. Find domain of rational functions. Use arrow notation. Identify vertical asymptotes. Identify horizontal asymptotes. Use transformations to graph rational functions. Graph rational functions. Identify slant (oblique) asymptotes.

gilead
Télécharger la présentation

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. Rational Functions Lesson 2.6, page 326

  2. Objectives • Find domain of rational functions. • Use arrow notation. • Identify vertical asymptotes. • Identify horizontal asymptotes. • Use transformations to graph rational functions. • Graph rational functions. • Identify slant (oblique) asymptotes. • Solve applied problems with rational functions.

  3. Definition • rational function – a quotient of two polynomials where p(x) and q(x) are polynomials and where q(x) is not the zero polynomial.

  4. Solution: When the denominator x + 4 = 0, we have x = 4, so the only input that results in a denominator of 0 is 4. Thus the domain is {x|x  4} or (, 4)  (4, ). REVIEW: The graph of the function is the graph of y = 1/x translated to the left 4 units. REVIEWFind the domain of

  5. See Example 1, page 326. Check Point 1: Find the domain of each rational function.

  6. Arrow Notation, pg. 328 Symbol Meaning

  7. Rational Functions • different from other functions because they have asymptotes • Asymptote -- a line that the graph of a function gets closer and closer to as one travels along that line in either direction

  8. Vertical Asymptote -- of a rational function f(x) = p(x)/q(x) are found by determining the zeros of q(x) that are not also zeros of p(x). If p(x) and q(x) are polynomials with no common factors other than constants, we need to determine only the zeros of the denominator q(x). In other words: If a is a zero of the denominator, but not a zero of the numerator, then the line x = a is a vertical asymptote for the graph of the function. Note: The graph will never cross or touch a vertical asymptote. Asymptotes

  9. Vertical asymptotes, pg. 329 Look for values of x which would make the denominator = zero, at these values there will be EITHER a hole in the graph or a vertical asymptote. Which? • If the value that makes the denominator = zero also makes the numerator = zero, there is a hole. • If a value only makes the denominator = zero, a vertical asymptote exists. • If you evaluate f(x) at values that get very close to the x-value that creates a zero denominator, you notice f(x) gets very large or very small. (approaching pos. or neg. infinity as you get closer and closer to x)

  10. Determine the vertical asymptotes of the function. Factor to find the zeros of the denominator: x2 4 = (x + 2)(x  2) Thus the vertical asymptotes are the lines x = 2 and x = 2. Try this.

  11. See Example 2, page 330. Check Point 2: Find the vertical asymptotes, if any, of each rational function.

  12. Horizontal Asymptotes, page 332 Horizontal Asymptote -- determined by the degrees of the numerator and denominator Form: y = a Note: Graph can cross or touch this asymptote.

  13. HORIZONTAL ASYMPTOTESLook at the rational function • If degree of Q(x) > degree of P(x) (BOB) horizontal asymptote y = 0 (x-axis). • If degree of Q(x) = degree of P(x) (same) horizontal asymptote y = • If degree of P(x) > degree of Q(x), (TUB) no horizontal asymptote

  14. See Example 3, page 332. Check Point 3: Find the horizontal asymptote, if any, of each rational function.

  15. Find the horizontal asymptote: More Practice

  16. Remember… • The graph of a rational function never crosses a vertical asymptote. • The graph of a rational function might cross a horizontal asymptote, but does not necessarily do so.

  17. y 5 x -5 -5 5 See Example 4, page 334. Check Point 4:

  18. y 5 x -5 -5 5 Strategy for Graphing a Rational Function (blue box, page 334) See Example 5, page 335. Check Point 5:

  19. y 5 x -5 -5 5 See Example 6, page 336. Check Point 6:

  20. y 5 x -5 -5 5 See Example 7, page 337. Check Point 7:

  21. ANOTHER Type of ASYMPTOTE:Oblique (or Slant) Asymptote If thedegree of P(x) is one greater than the degree of Q(x), you have a slant asymptote. To find oblique asymptote: • Divide numerator by denominator • Disregard remainder • Set quotient equal to y (This gives the equation of the asymptote.)

  22. What is the equation of the oblique asymptote? a) y = 4x – 3 b) y = 2x – 5/2 c) y = 2x – ½ d) y = 4x + 1

  23. See Example 8, page 339 • Check Point 8: Find the slant asymptote for

  24. ASYMPTOTE SUMMARYOccurrence of Lines as Asymptotes For a rational function f(x) = p(x)/q(x), where p(x) and q(x) have no common factors other than constants: • Vertical asymptotes occur at any x-values that make the denominator 0, but doesn’t make the numerator 0. • The x-axis (y = 0)is the horizontal asymptote when the degree of the numerator is less than the degree of the denominator. • A horizontal asymptote other than the x-axis occurs when the numerator and the denominator have the same degree.

  25. ASYMPTOTE SUMMARY (continued) • An oblique asymptote occurs when the degree of the numerator is one greater than the degree of the denominator. • There can be only one horizontal asymptote or one oblique asymptote and never both. • An asymptote is not part of the graph of the function.

  26. Graph 1) What makes the denominator equal zero? Because x= 1/2 and 3, the domain excludes these values. The graph has vertical asymptotes at x = 3 and x = 1/2. We sketch these with dashed lines. 2) Because the degree of the numerator is less than the degree of the denominator, the x-axis, y = 0, is the horizontal asymptote.

  27. Graph Example continued 3) Find the zeros. 4.) We find f(0), the y-intercept: Thus (0, 1) is the y-intercept.

  28. x f(x) 1 1/2 1  2/3 2 1 4 7/9 Example continued 5. We find other function values to determine the general shape of the graph and then draw the graph.

  29. Graph the following functions. a) b) c)

  30. Graph a: • Vertical Asymptote x = 2 • Horizontal Asymptote y = 1 • x-intercept (3, 0) • y-intercept (0, 3/2)

  31. Graph b: • Vertical Asymptote x = 3, x = 3 • Horizontal Asymptote y = 1 • x-intercepts (2.828, 0) • y-intercept (0, 8/9)

  32. Graph c: • Vertical Asymptote x = 1 • Oblique Asymptote y = x 1 • x-intercept (0, 0) • y-intercept (0, 0)

More Related