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Calculus 1 : Functions

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Example Questions

Example Question #513 : Other Differential Functions

As per the mean value theorem, there exists at least one value x=c within the interval (1,b) such that f'(c)=4 . For the function, interval, and derivative value f(x)=e^x , (1,b) , f'(c)=4 find a value of that validates the mean value theorem

Possible Answers:

1.22

4.66

1.73

1.05

6.34

Correct answer:

1.73

Explanation:

The mean value theorem states that for a planar arc passing through a starting and endpoint (a,b);a<b , there exists at a minimum one point, , within the interval (a,b) for which a line tangent to the curve at this point is parallel to the secant passing through the starting and end points.

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, f(x)=e^x , (1,b) , f'(c)=4 , we'll in turn wish to solve for to validate the mean value theorem:

$4=\frac{e^b-e^1}{b-1}$

Solving for gives the solution:

b=1.73

Which is, as expected, greater than to allow the creation of an interval.

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Example Question #514 : Other Differential Functions

As per the mean value theorem, there exists at least one value x=c within the interval (-1,b) such that f'(c)=0.8 . For the function, interval, and derivative value f(x)=3^x , (-1,b) , f'(c)=16 , find a value of that validates the mean value theorem.

Possible Answers:

3.99

4.81

2.96

5.67

11.42

Correct answer:

3.99

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, f(x)=3^x , (-1,b) , f'(c)=16 , we'll in turn wish to solve for to validate the mean value theorem:

$16=\frac{3^b-3^{-1}}{b-(-1)}$

Solving for gives the solution:

b=3.99

Which is, as expected, greater than to allow the creation of an interval.

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Example Question #515 : Other Differential Functions

As per the mean value theorem, there exists at least one value x=c within the interval (1,b) such that f'(c)=1.5 . For the function, interval, and derivative value f(x)=x^2-4x , (1,b) , , find a value of that validates the mean value theorem.

Possible Answers:

1.5

2.5

3.5

5.5

4.5

Correct answer:

4.5

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, f(x)=x^2-4x , (1,b) , f'(c)=1.5 , we'll in turn wish to solve for to validate the mean value theorem:

$1.5=\frac{(b^2-4b)-(1^2-4(1))}{b-1}$

1.5(b-1)=b^2-4b+3

b^2-5.5b+4.5

Solving for gives the solution:

b=4.5

Which is, as expected, greater than to allow the creation of an interval.

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Example Question #516 : Other Differential Functions

As per the mean value theorem, there exists at least one value x=c within the interval (0,b) such that f'(c)=-0.75 . For the function, interval, and derivative value f(x)=x^3-x , (0,b) , find a value of that validates the mean value theorem.

Possible Answers:

0.75

-0.25

0.25

0.5

-0.5

Correct answer:

0.5

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, f(x)=x^3-x , (0,b) , f'(c)=-0.75 , we'll in turn wish to solve for to validate the mean value theorem:

$-0.75=\frac{(b^3-b)-(0^3-0)}{b-0}$

Solving for via numerical solver gives the solution:

$b=\pm 0.5$

Choosing the positive solution for the sake of the interval leaves

b=0.5

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Example Question #1731 : Calculus

As per the mean value theorem, there exists at least one value x=c within the interval (2,b) such that f'(c)=5 . For the function, interval, and derivative value $f(x)=e^{x-1}$ , (2,b) , f'(c)=5 , find a value of that validates the mean value theorem.

Possible Answers:

2.88

2.45

4.04

3.69

3.12

Correct answer:

3.12

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, $f(x)=e^{x-1}$ , (2,b) , f'(c)=5 , we'll in turn wish to solve for to validate the mean value theorem:

$5=\frac{(e^{b-1})-(e^{2-1})}{b-2}$

Solving for using a calculator gives the solution:

b=3.12

Which is, as expected, greater than to allow the creation of an interval.

Report an Error

Example Question #1731 : Calculus

As per the mean value theorem, there exists at least one value x=c within the interval (3,b) such that f'(c)=20 . For the function, interval, and derivative value $f(x)=e^{x^2-8}$ , (3,b) , , find a value of that validates the mean value theorem.

Possible Answers:

3.06

4.57

4.86

4.02

3.44

Correct answer:

3.06

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, $f(x)=e^{x^2-8}$ , (3,b) , f'(c)=20 , we'll in turn wish to solve for to validate the mean value theorem:

$20=\frac{(e^{b^2-8})-(e^{3^2-8})}{b-3}$

Solving for using a calculator gives the solution:

b=3.06

Which is, as expected, greater than , albeit just barely, to allow the creation of an interval.

Report an Error

Example Question #518 : Other Differential Functions

As per the mean value theorem, there exists at least one value x=c within the interval (4,b) such that f'(c)=50 . For the function, interval, and derivative value f(x)=x^3-x^2-x , (4,b) , , find a value of that validates the mean value theorem.

Possible Answers:

8.31

5.63

-7.92

4.92

7.92

Correct answer:

4.92

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, f(x)=x^3-x^2-x , (4,b) , f'(c)=50 , we'll in turn wish to solve for to validate the mean value theorem:

$50=\frac{(b^3-b^2-b)-(4^3-4^2-4)}{b-4}$

Solving for using a calculator gives the solution:

b=-7.92,4.92

There are two solutions to the equation; elect the value larger than to allow creation of an interval:

b=4.92

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Example Question #708 : Differential Functions

As per the mean value theorem, there exists at least one value x=c within the interval (1,b) such that f'(c)=-4 . For the function, interval, and derivative value f(x)=x^2-e^x , (1,b) , , find a value of that validates the mean value theorem.

Possible Answers:

3.33

2.84

4.75

5.11

-4.51

Correct answer:

2.84

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, f(x)=x^2-e^x , (1,b) , f'(c)=-4 , we'll in turn wish to solve for to validate the mean value theorem:

$-4=\frac{(b^2-e^b)-(1^2-e^1)}{b-1}$

Solving for using a calculator gives the solution:

b=-4.51,2.84

To enable the creation of an interval, elect the value greater than a:

b=2.84

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Example Question #709 : Differential Functions

As per the mean value theorem, there exists at least one value x=c within the interval (-2,b) such that f'(c)=25 . For the function, interval, and derivative value f(x)=x^3+e^x , (-2,b) , , find a value of that validates the mean value theorem.

Possible Answers:

-1.08

0.91

3.31

4.27

3.99

Correct answer:

4.27

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, f(x)=x^3+e^x , (-2,b) , f'(c)=25 , we'll in turn wish to solve for to validate the mean value theorem:

$25=\frac{(b^3+e^b)-((-2)^3+e^{-2})}{b-(-2)}$

Solving for using a calculator gives the solution:

b=-3.68,4.27

Elect the value that is greater than a to complete the interval:

b=4.27

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Example Question #710 : Differential Functions

As per the mean value theorem, there exists at least one value x=c within the interval (-3,b) such that f'(c)=0 . For the function, interval, and derivative value $f(x)=x^3+e^{x^2}$ , (-3,b) , f'(c)=0 , find a value of that validates the mean value theorem.

Possible Answers:

2.66

3.00

3.38

4.12

1.91

Correct answer:

3.00

Explanation:

Meanvaluetheorem

In other words, if one were to draw a straight line through these start and end points, one could find a point on the curve where the tangent would have the same slope as this line.

$f'(c)=\frac{f(b)-f(a)}{b-a}=\frac{Rise}{Run};a<c<b$

Using our function, interval, and derivative definitions, $f(x)=x^3+e^{x^2}$ , (-3,b) , f'(c)=0 , we'll in turn wish to solve for to validate the mean value theorem:

$0=\frac{(b^3+e^{b^2})-((-3)^3+e^{(-3)^2})}{b-(-3)}$

Solving for using a calculator gives the solution:

b=3.00

Which is, as expected, greater than to allow the creation of an interval.

Report an Error

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Calculus 1 : Functions

Study concepts, example questions & explanations for Calculus 1

All Calculus 1 Resources

Example Questions

Example Question #513 : Other Differential Functions

Example Question #514 : Other Differential Functions

Example Question #515 : Other Differential Functions

Example Question #516 : Other Differential Functions

Example Question #1731 : Calculus

Example Question #1731 : Calculus

Example Question #518 : Other Differential Functions

Example Question #708 : Differential Functions

Example Question #709 : Differential Functions

Example Question #710 : Differential Functions

All Calculus 1 Resources

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