Deck 3: Applications of the Derivative

If f has a local minimum at x = 2, then what can you say about $f ^ { \prime } ( 2 )$ ? What if you also know that f is differentiable at x = 2?

If a continuous and differentiable function f has zeros at $x = - 2$ , $x = 2$ , and $x = 5$ , what can you say about $f ^ { \prime }$ on [-2, 5]?

If a continuous and differentiable function f is equal to - 3 at $x = - 2$ and $x = 2$ , what can you say about $f ^ { \prime }$ on [-2, 2]?

If a function f is continuous and differentiable everywhere, $f ( - 1 ) = 4 , \text { and } f ( 2 ) = 3$ What can you say about $f ^ { \prime }$ on [-1, 2]?

A function f that is defined on [-1, 3] with $f ( - 1 ) = f ( 3 ) = 2$ such that f is continuous everywhere, differentiable everywhere except at $x = 1$ but fails the conclusion of Rolle's Theorem. Explain why it doesn't satisfy the Rolle's Theorem?

Find the critical points of $f ( x ) = \frac { \ln 4 x } { 2 x }$

Find the critical points of $f ( x ) = \csc x$

Find the critical points of $f ( x ) = \sin x$

Find the critical points of $f ( x ) = ( 2 x + 1 ) ^ { 3 }$

Find the critical points of $f ( x ) = 6 x ^ { 4 } - 16 x ^ { 3 } - 24 x ^ { 2 } + 24 x$

Find the critical points of $f ( x ) = e ^ { x } \left( x ^ { 2 } - 2 x \right)$

Determine whether or not the function $f ( x ) = x ^ { 3 } - 3 x ^ { 2 } + 2 x$ satisfies the hypothesis of Rolle's Theorem on the interval [0, 2]. If it does, find the exact values of all $c \in ( 0,2 )$ that satisfy the conclusion of Rolle's Theorem.

Determine whether or not the function $f ( x ) = \cos 2 x$ satisfies the hypothesis of Rolle's Theorem on the interval $\left[ \frac { \pi } { 4 } , \frac { 3 \pi } { 4 } \right]$ If it does, find the exact values of all values of $c \in \left( \frac { \pi } { 4 } , \frac { 3 \pi } { 4 } \right)$ that satisfy the conclusion of Rolle's Theorem.

Determine whether or not the function $f ( x ) = e ^ { x } \left( x ^ { 2 } - 3 x \right)$ satisfies the hypothesis of Rolle's Theorem on the interval [0, 3]. If it does, find the exact values of all $c \in ( 0,3 )$ that satisfy the conclusion of Rolle's Theorem.

Does $f ( x ) = 2 x ^ { 2 } + \frac { 1 } { x }$ satisfy the hypothesis of the Mean Value Theorem on the interval [-1, 2]. If it does, then find the exact values of all $c \in ( - 1,2 )$ that satisfy the conclusion of the Mean Value Theorem.

Does $f ( x ) = \sqrt { x + 4 }$ satisfy the hypothesis of the Mean Value Theorem on the interval [0, 5]. If it does, then find the exact values of all $c \in ( 0,5 )$ that satisfy the conclusion of the Mean Value Theorem.

Does $f ( x ) = x ^ { 3 } - 2 x ^ { 2 } + 1$ satisfy the hypothesis of the Mean Value Theorem on the interval [0,3]. If it does, then find the exact values of all $c \in ( 0,3 )$ that satisfy the conclusion of the Mean Value Theorem.

If two functions $f ( x ) \text { and } g ( x )$ have the same derivatives, then what can you say about the function $f ( x ) - g ( x )$ ?

Determine the intervals on which $f ( x ) = x ^ { 3 } - 4 x ^ { 2 } + 1$ is increasing and decreasing.

Determine the intervals on which $f ( x ) = e ^ { x } ( x - 3 )$ is increasing and decreasing.

Determine the intervals on which $f ( x ) = \frac { 2 x + 1 } { x ^ { 2 } - 4 }$ is increasing and decreasing.

Determine the intervals on which $f ( x ) = \frac { x } { x ^ { 2 } + 1 }$ is increasing and decreasing.

Determine the intervals on which $f ( x ) = \sin ^ { 2 } x$ is increasing and decreasing.

Determine the intervals on which $f ( x ) = \ln \left( x ^ { 2 } + 2 \right)$ is increasing and decreasing.

Determine the intervals on which $f ( x ) = \frac { e ^ { x } } { 2 + e ^ { x } }$ is increasing and decreasing.

Use the first derivative test to determine the local extrema of $f ( x ) = ( x - 1 ) ^ { 2 } ( x + 2 )$

Use the first derivative test to determine the local extrema of $f ( x ) = \frac { ( x - 2 ) ^ { 2 } } { x + 1 }$

Use the first derivative test to determine the local extrema of $f ( x ) = e ^ { x } \left( x ^ { 2 } - 3 x + 2 \right)$

Use the first derivative test to determine the local extrema of $f ( x ) = \arctan 2 x$

Sketch the graph of a continuous function, if possible, such that $f < 0 \text { on } ( - 2 , \infty )$ , $f > 0 \text { on } ( - \infty , - 2 )$ , $f ^ { \prime } < 0 \text { on } ( - \infty , \infty )$ and $f ^ { \prime \prime } > 0 \text { on } ( - \infty , - 1 )$ , but $f ^ { \prime \prime } < 0 \text { on } ( - 1 , \infty )$

Sketch the graph of a continuous function, if possible, such that $f < 0 \text { on } ( - \infty , 1 )$ , $f > 0 \text { on } ( 1 , \infty )$ , $f ^ { \prime } > 0 \text { on } ( - \infty , \infty )$ , $f ^ { \prime \prime } > 0 \text { on } ( - \infty , 1 )$ and $f ^ { \prime \prime } < 0 \text { on } ( 1 , \infty )$

Sketch the graph of a continuous function, if possible, such that $f > 0 \text { on } ( - \infty , - 4 )$ and $( 0 , \infty )$ , $f < 0 \text { on } ( - 4,0 )$ , $f ^ { \prime } > 0 \text { on } ( - 2 , \infty )$ , $f ^ { \prime } < 0 \text { on } ( - \infty , - 2 )$ and $f ^ { \prime \prime } > 0 \text { on } ( - \infty , \infty )$

Sketch the graph of a continuous function, if possible, such that $f ^ { \prime } < 0 \text { on } ( - \infty , 2 )$ $f ^ { \prime } > 0 \text { on } ( 2 , \infty )$ , $f ( 2 ) = 0$ and $f ^ { \prime \prime } > 0 \text { on } ( - \infty , \infty )$

Sketch the graph of a continuous function, if possible, such that $f < 0 \text { on } ( - \infty , 4 )$ , $f > 0 \text { on } ( 4 , \infty )$ , $f ^ { \prime } > 0 \text { on } ( - \infty , 0 )$ and $( 8 / 3 , \infty )$ , $f ^ { \prime } < 0 \text { on } ( 0,8 / 3 )$ , $f ^ { \prime \prime } > 0 \text { on } ( 4 / 3 , \infty )$ , but $f ^ { \prime \prime } < 0 \text { on } ( - \infty , 4 / 3 )$

Sketch the graph of a continuous function, if possible, such that $f < 0 \text { on } ( - \infty , 0 )$ , $f > 0 \text { on } ( 0 , \infty )$ , and $f ^ { \prime } > 0 \text { on } ( - \infty , 1 / 3 ) \text { and } ( 1 , \infty )$ $f ^ { \prime } < 0 \text { on } ( 1 / 3,1 )$ and $f ^ { \prime \prime } > 0 \text { on } ( 2 / 3 , \infty )$ and $f ^ { \prime \prime } < 0 \text { on } ( - \infty , 2 / 3 )$

Sketch the graph of a continuous function, if possible, such that $f ^ { \prime }$ does not exist at $x = 0 , f ^ { \prime \prime } > 0$ on $( 0 , \infty )$ , $f ( x ) > 0$ on $( 1,5 ) , f ( x ) < 0$ on $( - \infty , 1 ]$ and on $[ 5 , \infty ) , f ^ { \prime } ( x ) > 0$ on $( - \infty , 3 ) , f ^ { \prime } < 0$ on $( 3 , \infty )$ , and $f ^ { \prime } ( x )$ does not exist at $x = 3$ .

Sketch labeled graphs of each function $f ( x ) = x ^ { 2 } + 5 x$ by hand. As part of your work make sign charts for the signs, roots and undefined points of $f , f ^ { \prime } \text { and } f$

Sketch labeled graphs of each function $f ( x ) = ( x - 1 ) ( x + 2 )$ by hand. As part of your work make sign charts for the signs, roots and undefined points of $f , f ^ { \prime } \text { and } f^{\prime \prime }$

Sketch labeled graphs of each function $f ( x ) = x ^ { 3 } + 2 x ^ { 2 }$ by hand. As part of your work make sign charts for the signs, roots and undefined points of $f , f ^ { \prime } \text { and } f ^ { \prime\prime }$

Sketch labeled graphs of each function $f ( x ) = \frac { - 1 } { x ^ { 2 } + 2 }$ by hand. As part of your work make sign charts for the signs, roots and undefined points of $f , f ^ { \prime } \text { and } f^ { \prime\prime }$

Sketch labeled graphs of each function $f ( x ) = \frac { x } { x ^ { 2 } + 4 }$ by hand. As part of your work make sign charts for the signs, roots and undefined points of $f , f ^ { \prime } \text { and } f^ { \prime\prime }$

Sketch labeled graphs of each function $f ( x ) = \ln 2 x + 1$ by hand. As part of your work make sign charts for the signs, roots and undefined points of $f , f ^ { \prime } \text { and } f^ { \prime \prime}$

Sketch labeled graphs of each function $f ( x ) = e ^ { - x ^ { 2 } }$ by hand. As part of your work make sign charts for the signs, roots and undefined points of $f , f ^ { \prime } \text { and } f^ { \prime\prime }$

Use a sign chart to determine the intervals on which $f ( x ) = ( x + 3 ) ^ { 4 }$ is concave up and concave down, and identify the locations of any inflection points.

Use a sign chart to determine the intervals on which $f ( x ) = \frac { 1 } { x ^ { 2 } + 4 }$ is concave up and concave down, and identify the locations of any inflection points.

Use a sign chart to determine the intervals on which $f ( x ) = e ^ { 2 x } \left( 1 - e ^ { x } \right)$ is concave up and concave down, and identify the locations of any inflection points.

Use a sign chart to determine the intervals on which $f ( x ) = ( x - 2 ) ^ { 3 } ( x - 1 )$ is concave up and concave down, and identify the locations of any inflection points.

Use a sign chart to determine the intervals on which $f ( x ) = x ^ { 3 } - 3 x + 1$ is concave up and concave down, and identify the locations of any inflection points.

Use the derivative $f ^ { \prime } ( x ) = \frac { 2 } { x }$ to find the local extrema and inflection points of $f$

Use the derivative $f ^ { \prime } ( x ) = e ^ { 2 x } ( x + 2 )$ to find the local extrema and inflection points of $f$

Use the derivative $f ^ { \prime } ( x ) = x ^ { 3 } - 4 x ^ { 2 } + 4 x$ to find the local extrema and inflection points of $f$

Use the derivative $f ^ { \prime } ( x ) = x ^ { 4 } - 2$ to find the local extrema and inflection points of $f$

Find the location and values of any global extrema of $f ( x ) = x ^ { 3 } - 3 x ^ { 2 } - 9 x$ on the intervals: (a) [-2, 3](b) [-2, 4]

Find the location and values of any global extrema of $f ( x ) = 3 x ^ { 4 } - 4 x ^ { 3 } - 6 x ^ { 2 } + 12 x$ on the intervals: (a) (-2, 1](b) [-2, 1]

Find the location and values of any global extrema of $f ( x ) = x - 2 \cos x$ on $\left[ - \frac { \pi } { 4 } , \frac { \pi } { 2 } \right]$

Find the location and values of any global extrema of $f ( x ) = \frac { x - 2 } { x + 1 }$ on [-2, 4).

Jen needs to make a flyer for her dog's birthday party. She wants the flyer to contain 40 square inches of printed portion and she wants to use 2 inches of each side as well as two inches of top and bottom of the paper for decoration. What size of paper should Jen choose in order to use the least amount of paper per flyer?

Find the point(s) on the curve $y = x ^ { 2 }$ that is closest to the point (3, 0).

Find the point(s) on the curve $y = x ^ { 2 }$ that is closest to the point (0, 3).

Find two numbers whose product is 12 and whose sum of squares is minimum?

My brother wants to make an open-topped box out of a 4 × 6 square feet piece of cardboard by cutting identical squares from the corners and folding up the sides. What is the dimension of each square he will cut out of each corner in order to maximize the volume of the box he makes?

A veterinarian has 90 ft. of fence and he wants to enclose a rectangular dog-run along the 60-feet long back side of his office building. He will not fence the side along the building. What are the dimensions of the dog-run that gives the maximum area he desires?

A veterinarian wants to make three identical adjoining dog-runs in the backyard of his office building. He needs each dog-run to be 400 square feet. What are the dimensions of each dog-run that requires the minimum amount of fencing material?

Melissa wants to make a rectangular box with a square base and cover its top and bottom faces by velvet which will cost her $3 per square inch and the sides by silk which will cost her $5 per square inch. The box should have a volume of 1600 cubic inches. Find the dimensions of the box that will cost her the least amount of money.

The cost of the material for the top and bottom of a cylindrical can is 10 cents per square inch. The material for the rest of the can costs 5 cents per square inch. If the can must hold 500 cubic inches of liquid, what dimensions should be chosen to make the cheapest can?

Given $u = u ( t ) , \quad v = v ( t ) , \quad w = w ( t )$ are functions of t, calculate the derivative of the functions:
(a) $f ( t ) = u ^ { 2 } + 3 v$
(b) $f ( t ) = 2 u \sqrt { v - w }$

Given $u = u ( t ) , \quad v = v ( t ) , \quad w = w ( t )$ are functions of t, calculate the derivative of the functions:
(a) $f ( t ) = t u + 5 u ^ { 3 } v$
(b) $f ( t ) = \frac { 2 u } { v w }$

Given $u = u ( t ) , \quad v = v ( t ) , \quad w = w ( t )$ are functions of t, calculate the derivative of the functions:
(a) $f ( t ) = ( u + v ) ^ { 2 } + 2 t w$
(b) $f ( t ) = \frac { 3 } { u ^ { 2 } v }$

Find $\lim _ { x \rightarrow 2 } \frac { x ^ { 2 } + x - 6 } { x - 2 }$

Find $\lim _ { x \rightarrow 1 } \frac { x ^ { 2 } - 3 x + 2 } { x - 1 }$

Find $\lim _ { x \rightarrow - \infty } \frac { x + 2 } { 3 - 2 x ^ { 2 } }$

Find $\lim _ { x \rightarrow \infty } \frac { e ^ { 2 x } } { 1 + e ^ { 5 x } }$

Find $\lim _ { x \rightarrow \infty } \frac { 2 ^ { x } } { 1 + 3 ^ { x } }$

Find $\lim _ { x \rightarrow 0 } \frac { 2 \cos x - 2 } { \sin 2 x }$

Find $\lim _ { x \rightarrow 0 ^ { + } } x ^ { 3 x }$

Find $\lim _ { x \rightarrow \infty } x ^ { 2 / x }$

Find $\lim _ { x \rightarrow 0 ^ { + } } x ^ { \sin x }$

Find $\lim _ { x \rightarrow 0 ^ { + } } \left( e ^ { 3 x } - 1 \right) ^ { x }$

Find $\lim _ { x \rightarrow 0 } \left( e ^ { x } + x \right) ^ { 1 / x }$