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Zooming In. Objectives. To define the slope of a function at a point by zooming in on that point. To see examples where the slope is not defined. ES: Explicitly assessing information and drawing conclusions. Zooming In.
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Objectives • To define the slope of a function at a point by zooming in on that point. • To see examples where the slope is not defined. • ES: Explicitly assessing information and drawing conclusions
Zooming In • Most functions we see in calculus have the property that if we pick a point on the graph of the function and zoom in, we will see a straight line.
Zooming In A. Graph the function: f (x) = x3 – 6x2 + 11x – 4 B. Zoom in on the point (4, 8) until the graph looks like a straight line. C. Pick a point on the curve other than the point (4, 8) and estimate the coordinates of this point. D. Calculate the slope of the line through these two points.
Zooming In • The slope of a function is called its derivative, and is denoted f’ (x) . • The number we just computed is an approximation for the slope or derivative of f (x) = x3 – 6x2 + 11x – 4 at the point (4, 8). • Since the slope of f (x) atx = 4 equals 11, we writef’ (4) = 11.
Zooming In • Local linearity is a property of differentiable functions that says that if you zoom in on a point on the graph of the function, the graph will eventually look like a straight line with a slope equal to the derivative of the function at the point. • A function is differentiable at a point if its derivative exists at that point.
Zooming In • Not every function has a derivative at all of its points. • Graph the function f (x) = |x| and zoom in at the point (0, 0). • Notice that f’ (0)doesnotexist, because as we zoom in on (0, 0) the graph doesnot look like a straight line.
Conclusion • The slope of a function is called its derivative. • Local linearity is a property of differentiable functions. • Not every function has a derivative at all of its points.