1 / 46

Lesson 3-1: Derivatives

Lesson 3-1: Derivatives. AP Calculus Mrs. Mongold. We write:. There are many ways to write the derivative of. is called the derivative of at. “The derivative of f with respect to x is …”. “the derivative of f with respect to x”. “f prime x”. or. “y prime”.

aminia
Télécharger la présentation

Lesson 3-1: Derivatives

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. Lesson 3-1: Derivatives AP Calculus Mrs. Mongold

  2. We write: There are many ways to write the derivative of is called the derivative of at . “The derivative of f with respect to x is …”

  3. “the derivative of f with respect to x” “f prime x” or “y prime” “the derivative of y with respect to x” or “dee why dee ecks” “the derivative of f with respect to x” or “dee eff dee ecks” “the derivative of f of x” “dee dee ecks uv eff uv ecks” or

  4. Note: dx does not mean d times x ! dy does not mean d times y !

  5. does not mean ! does not mean ! Note: (except when it is convenient to think of it as division.) (except when it is convenient to think of it as division.)

  6. does not mean times ! Note: (except when it is convenient to treat it that way.)

  7. The derivative is the slope of the original function. The derivative is defined at the end points of a function on a closed interval.

  8. A function is differentiable if it has a derivative everywhere in its domain. It must be continuous and smooth. Functions on closed intervals must have one-sided derivatives defined at the end points. p

  9. Example • Differentiate f(x)=x3

  10. Example • Differentiate f(x)=x3 To differentiate we take the limit

  11. Example • Differentiate f(x)=x3 To differentiate we take the limit

  12. Example • Differentiate f(x)=x3 To differentiate we take the limit

  13. Example • Differentiate f(x)=x3 To differentiate we take the limit

  14. Example • Differentiate f(x)=x3 To differentiate we take the limit

  15. Example • Differentiate f(x)=x3 To differentiate we take the limit

  16. Example • Differentiate f(x)=x3 To differentiate we take the limit

  17. Example • Differentiate f(x)=

  18. Example • Differentiate f(x)= So look at the limit

  19. Example • Differentiate f(x)= So look at the limit

  20. Example • Differentiate f(x)= So look at the limit

  21. Example • Differentiate f(x)= So look at the limit

  22. Example • Differentiate f(x)= So look at the limit

  23. Example • Differentiate f(x)= So look at the limit

  24. Example • Differentiate f(x)= So look at the limit

  25. Alternate Definition • Derivative at a point • The derivative of a function f at the point x=a is the limit Provided the limit exists

  26. Example • Use Alt. Def. to differentiate f(x)= at x=a

  27. Example • Use Alt. Def. to differentiate f(x)= at x=a • Alt. Def. Limit is

  28. Example • Use Alt. Def. to differentiate f(x)= at x=a • Alt. Def. Limit is

  29. Example • Use Alt. Def. to differentiate f(x)= at x=a • Alt. Def. Limit is

  30. Example • Use Alt. Def. to differentiate f(x)= at x=a • Alt. Def. Limit is

  31. Example • Use Alt. Def. to differentiate f(x)= at x=a • Alt. Def. Limit is Domain (0,

  32. Example • Use Alt. Def. to differentiate f(x)= at a=2

  33. Example • Use Alt. Def. to differentiate f(x)= at a=2 • Previous example gave us

  34. Example • Use Alt. Def. to differentiate f(x)= at a=2 • Previous example gave us • So when a = 2 then

  35. Lots to Remember with derivatives • The derivative is the slope at a point • When graphing a derivative the x values stay the same, but the y-values for the graph of f’ are the slopes from the points on f • So positive slope means f’ graph is above x axis • So negative slope means f’ graph is below x axis • 0 slope means f’ graph crosses the x axis

  36. Example • Graph the derivative of f

  37. Example • Graph the derivative of f

  38. Example • Graph the derivative of f

  39. Example • Graph the derivative of f

  40. Example • If f(x) = x3-x, find a formula for f’(x) and illustrate by comparing f and f’ graphs

  41. Example • Graph f from f’ • Sketch a graph of a function f that has the following properties • f(0)=0, f( • The graph of f’, the derivative of f, is below on left • F is continuous for all x

  42. Example • Graph f from f’ • Sketch a graph of a function f that has the following properties • f(0)=0 • The graph of f’, the derivative of f, is below on left • F is continuous for all x

  43. Example • Sketch the graph of a continuous function f , with f(0) = -1 and

  44. Example • Sketch the graph of a continuous function f , with f(0) = -1 and -1

  45. Homework • Page 101/ 1-12 in Blue and Red Calc Book

More Related