$\"\"$

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The function is $\"\"$ , $\"\"$ .

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Mean value theorem :

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Let $\"\"$ be a function that satisfies the following three hypotheses.

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1. $\"\"$ is continuous on $\"\"$ .

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2. $\"\"$ is differentiable on $\"\"$ .

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Then there is a number $\"\"$ in $\"\"$ such that $\"\"$ .

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$\"\"$

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The function is $\"\"$ .

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The function is continuous on the interval $\"\"$ .

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Differentiate $\"\"$ on each side with respect to $\"\"$ .

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$\"\"$

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The function is differentiable on the interval $\"\"$ .

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Then $\"\"$ .

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$\"\"$

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From the mean value theorem :

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$\"\"$

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Substitute $\"\"$ in $\"\"$ .

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$\"\"$

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$\"\"$

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Find the tangent line at $\"\"$ .

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From the above $\"\"$ .

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Then $\"\"$ .

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Therefore the tangent line at a point is $\"\"$ .

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The slope of the tangent is the derivative of the function.

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Slope of the tangent line is $\"\"$ .

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Point - slope form of a line equation with a point $\"\"$ : $\"\"$ .

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Substitute $\"\"$ and $\"\"$ in the point - slope form.

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$\"\"$

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The tangent line equation is $\"\"$ .

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$\"\"$

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Find the secant line through the end points.

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The end points are $\"\"$ and $\"\"$ .

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$\"\"$ .

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$\"\"$ .

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Slope of the secant line is $\"\"$ .

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Point - slope form of a line equation with a point $\"\"$ : $\"\"$ .

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Substitute $\"\"$ in the point - slope form.

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$\"\"$

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The secant line equation is $\"\"$ .

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$\"\"$

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Graph :

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Graph the function $\"\"$ :

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(1) Draw the coordinate plane.

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(2) Draw the tangent line equation is $\"\"$ .

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(3) Draw the secant line equation is $\"\"$ .

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$\"\"$

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The tangent line equation are $\"\"$ .

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The secant line equation is $\"\"$ .

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Graph of the function, tangent line and secant line on same graph :

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$\"\"$ .