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Implicit Differentiation - Used in cases where it is impossible to solve for “y” as an explicit function of “x”

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Presentation on theme: "Implicit Differentiation - Used in cases where it is impossible to solve for “y” as an explicit function of “x”"— Presentation transcript:

1 Implicit Differentiation - Used in cases where it is impossible to solve for “y” as an explicit function of “x”

2 Implicit Differentiation - Used in cases where it is impossible to solve for “y” as an explicit function of “x”

3 Implicit Differentiation - Used in cases where it is impossible to solve for “y” as an explicit function of “x”

4 Implicit Differentiation

5 OK, here is how I like to attack these :

6 Implicit Differentiation OK, here is how I like to attack these : - get your x’s and number together and take the derivative

7 Implicit Differentiation OK, here is how I like to attack these : - get your x’s and number together and take the derivative

8 Implicit Differentiation OK, here is how I like to attack these : - get your x’s and number together and take the derivative - get the y’s together and take the derivative

9 Implicit Differentiation OK, here is how I like to attack these : - get your x’s and number together and take the derivative - get the y’s together and take the derivative

10 Implicit Differentiation

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14 this is the derivative

15 Implicit Differentiation

16 Let’s get it in standard form :

17 Implicit Differentiation Let’s get it in standard form :

18 Implicit Differentiation Let’s get it in standard form : - get your x’s and number together and take the derivative

19 Implicit Differentiation Let’s get it in standard form : - get your y’s together and take the derivative

20 Implicit Differentiation Let’s get it in standard form :

21 Implicit Differentiation Let’s get it in standard form :

22 Implicit Differentiation Let’s get it in standard form :

23 Implicit Differentiation Let’s get it in standard form :

24 Implicit Differentiation Let’s get it in standard form : - This is your derivative

25 Implicit Differentiation

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29 - Use a and b again like we did with complex functions and the product rule…

30 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule…

31 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule…

32 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule…

33 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule…

34 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule…

35 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule…

36 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule…

37 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule…

38 Implicit Differentiation - Use a and b again like we did with complex functions and the product rule… - When you can, you should simplify as far as possible…

39 Implicit Differentiation

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49 - again, you should simplify as far as possible…

50 Implicit Differentiation Now substitute your ( - 5, 17 ) into your derivative to find the slope of the tangent line…

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