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Assignment 4 Section 3.1 The Derivative and Tangent Line Problem.

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Presentation on theme: "Assignment 4 Section 3.1 The Derivative and Tangent Line Problem."— Presentation transcript:

1 Assignment 4 Section 3.1 The Derivative and Tangent Line Problem

2 The Basic Question is… How do you find the equation of a line that is tangent to a function y=f(x) at an arbitrary point P? To find the equation of a line you need: a pointand a slope

3 How do you find the slope when the line is a tangent line?

4 First, we approximate with the secant line.

5 How do we make the approximation better? Choose h smaller… And smaller… How close to zero can it get? Infinitely

6 Definition of slope of the tangent line If f(x) is defined on an open interval (a,b) then the slope of the tangent line to the graph of y=f(x) at an arbitrary point (x,f(x)) is given by:

7 Example: #6—Find the slope of the tangent line to the graph of the function at the given point. (-2, -2)

8 The limit that is the slope of the tangent line is actually much more.. Definition of the Derivative of a Function The derivative of f at x is given by Provided the limit exists. For all x for which the limit exists, is a function of x.

9 Notations for derivative

10 Find the derivative by the limit process. #20 #24

11 Find an equation of the tangent line to th graph of f at the given point. #26 » ( - 3, 4)

12 #34 Find an equation of the line that is tangent to the graph of f and parallel to the given line.

13 Sketch the graph of f’ #46

14 What destroys the derivative at a point? a)Cusps b)Corners c)Vertical tangents

15 And… Points of Discontinuity Fact: If a function is differentiable at x=c, then f is continuous at x=c

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