1 / 33

Absolute-Value Functions

Absolute-Value Functions . Warm up Lesson Homework. 5. f ( x ) = x + 2; vertical stretch by a factor of 4. Warm Up Evaluate each expression for f (4) and f (-3). 1. f ( x ) = –| x + 1|. –5; –2. 2. f ( x ) = 2| x | – 1. 7; 5. 3. f ( x ) = | x + 1| + 2. 7; 4.

piera
Télécharger la présentation

Absolute-Value 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. Absolute-Value Functions Warm up Lesson Homework

  2. 5.f(x) = x + 2; vertical stretch by a factor of 4 Warm Up Evaluate each expression for f(4) and f(-3). 1.f(x) = –|x + 1| –5; –2 2.f(x) = 2|x| – 1 7; 5 3.f(x) = |x + 1| + 2 7; 4 Let g(x) be the indicated transformation of f(x). Write the rule for g(x). 4. f(x) = –2x + 5; vertical translation 6 units down g(x) = –2x– 1 g(x) = 2x + 8

  3. Your Goal Today is… Graph and transform absolute-value functions.

  4. Vocabulary absolute-value function

  5. An absolute-value function is a function whose rule contains an absolute-value expression. The graph of the parent absolute-value function f(x) = |x| has a V shape with a minimum point or vertex at (0, 0).

  6. The absolute-value parent function is composed of two linear pieces, one with a slope of –1 and one with a slope of 1. In Lesson 2-6, you transformed linear functions. You can also transform absolute-value functions.

  7. Remember! The general forms for translations are Vertical: g(x) = f(x) + k Horizontal: g(x) = f(x– h)

  8. Example 1A: Translating Absolute-Value Functions Perform the transformation on f(x) = |x|. Then graph the transformed function g(x). 5 units down f(x) = |x| g(x) = f(x) + k g(x) = |x| – 5 Substitute. The graph of g(x) = |x| – 5 is the graph of f(x) = |x| after a vertical shift of 5 units down. The vertex of g(x) is (0, –5).

  9. Example 1A Continued The graph of g(x) = |x|– 5 is the graph of f(x) = |x| after a vertical shift of 5 units down. The vertex of g(x) is (0, –5). f(x) g(x)

  10. Example 1B: Translating Absolute-Value Functions Perform the transformation on f(x) = |x|. Then graph the transformed function g(x). 1 unit left f(x) = |x| g(x) = f(x– h) g(x) = |x – (–1)| = |x + 1| Substitute.

  11. Example 1B Continued The graph of g(x) = |x + 1| is the graph of f(x) = |x| after a horizontal shift of 1 unit left. The vertex of g(x) is (–1, 0). f(x) g(x)

  12. Write In Your Notes! Example 1a Let g(x) be the indicated transformation of f(x) = |x|. Write the rule for g(x) and graph the function. 4 units down f(x) = |x| g(x) = f(x) + k g(x) = |x| – 4 Substitute.

  13. Check It Out! Example 1a Continued The graph of g(x) = |x| – 4 is the graph of f(x) = |x| after a vertical shift of 4 units down. The vertex of g(x) is (0, –4). f(x) g(x)

  14. Write In Your Notes! Example 1b Perform the transformation on f(x) = |x|. Then graph the transformed function g(x). 2 units right f(x) = |x| g(x) = f(x– h) g(x) = |x – 2| = |x –2| Substitute.

  15. Check It Out! Example 1b Continued The graph of g(x) = |x – 2| is the graph of f(x) = |x| after a horizontal shift of 2 units right. The vertex of g(x) is (2, 0). f(x) g(x)

  16. Because the entire graph moves when shifted, the shift from f(x) = |x| determines the vertex of an absolute-value graph.

  17. Example 2: Translations of an Absolute-Value Function Translate f(x) = |x|so that the vertex is at (–1, –3). Then graph. g(x) = |x – h| + k g(x) = |x – (–1)| + (–3) Substitute. g(x) = |x + 1| – 3

  18. Example 2 Continued The graph of g(x) = |x + 1| – 3 is the graph of f(x) = |x| after a vertical shift down 3 units and a horizontal shift left 1 unit. f(x) The graph confirms that the vertex is (–1, –3). g(x)

  19. Write In Your Notes! Example 2 Translate f(x) = |x| so that the vertex is at (4, –2). Then graph. g(x) = |x –h| + k g(x) = |x – 4| + (–2) Substitute. g(x) = |x –4| – 2

  20. f(x) g(x) Check It Out! Example 2 Continued The graph of g(x) = |x – 4| – 2 is the graph of f(x) = |x| after a vertical down shift 2 units and a horizontal shift right 4 units. The graph confirms that the vertex is (4, –2).

  21. Remember! Remember! Reflection across x-axis: g(x) = –f(x) Reflection across y-axis: g(x) = f(–x) Vertical stretch and compression : g(x) = af(x) Horizontal stretch and compression: g(x) = f Absolute-value functions can also be stretched, compressed, and reflected.

  22. Example 3A: Transforming Absolute-Value Functions Perform the transformation. Then graph. Reflect the graph. f(x) =|x –2| + 3 across the y-axis. g(x) = f(–x) Take the opposite of the input value. g(x) = |(–x) – 2| + 3

  23. g f Example 3A Continued The vertex of the graph g(x) = |–x – 2| + 3 is (–2, 3).

  24. Example 3B: Transforming Absolute-Value Functions Stretch the graph. f(x) = |x| – 1 vertically by a factor of 2. g(x) = af(x) g(x) = 2(|x| – 1) Multiply the entire function by 2. g(x) = 2|x| – 2

  25. f(x) g(x) Example 3B Continued The graph of g(x) = 2|x| – 2 is the graph of f(x) = |x| – 1 after a vertical stretch by a factor of 2. The vertex of g is at (0, –2).

  26. Substitute for b. Example 3C: Transforming Absolute-Value Functions Compress the graph of f(x) = |x + 2| – 1 horizontally by a factor of . g(x) = |2x + 2| – 1 Simplify.

  27. g Example 3C Continued The graph of g(x) = |2x + 2|– 1 is the graph of f(x) = |x + 2| – 1 after a horizontal compression by a factor of . The vertex of g is at (–1, –1). f

  28. Write In Your Notes! Example 3a Perform the transformation. Then graph. Reflect the graph. f(x) = –|x – 4| + 3 across the y-axis. g(x) = f(–x) Take the opposite of the input value. g(x) = –|(–x) – 4| + 3 g(x) = –|–x – 4| + 3

  29. Check It Out! Example 3a Continued The vertex of the graph g(x) = –|–x – 4| + 3 is (–4, 3). g f

  30. g(x) = (|x| + 1) Multiply the entire function by . g(x) = (|x| + ) Write In Your Notes! Example 3b Compress the graph of f(x) = |x| + 1 vertically by a factor of . g(x) = a(|x| + 1) Simplify.

  31. The graph of g(x) = |x| + is the graph of g(x) = |x| + 1 after a vertical compression by a factor of . The vertex of g is at ( 0, ). Check It Out! Example 3b Continued f(x) g(x)

  32. g(x) = f( x) g(x) = | (4x)| – 3 Write In Your Notes! Example 3c Stretch the graph. f(x) = |4x| – 3 horizontally by a factor of 2. Substitute 2 for b. Simplify. g(x) = |2x| – 3

  33. g f Check It Out! Example 3c Continued The graph of g(x) = |2x| – 3 the graph of f(x) = |4x| – 3 after a horizontal stretch by a factor of 2. The vertex of g is at (0, –3).

More Related