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Calculus 1 : How to find differential functions

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Example Questions

Example Question #1901 : Calculus

Let f(x)=ln(sin(x)) on the interval (0.8,1.6) . Find a value for the number(s) that satisfies the mean value theorem for this function and interval.

Possible Answers:

1.07

0.95

1.18

1.48

1.26

Correct answer:

1.18

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of f(x)=ln(sin(x)) on the interval (0.8,1.6)

f(0.8)=ln(sin(0.8))=-0.33

f(1.6)=ln(sin(1.6))=0

Then take the difference of the two and divide by the interval.

$\frac{0-(-0.33)}{1.6-0.8}=0.41$

Now find the derivative of the function; this will be solved for the value(s) found above.

Derivative of a natural log:

$d[ln(u)]=\frac{du}{u}$

Trigonometric derivative:

d[sin(u)]=cos(u)du

$f'(x)=\frac{cos(x)}{sin(x)}=cot(x)$

cot(x)=0.41

Using a calculator, we find the solution x=1.18 , which fits within the interval (0.8,1.6) , satisfying the mean value theorem.

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Example Question #1901 : Calculus

Let f(x)=ln(sin(x)) on the interval (0.8,1.6) . Find a value for the number(s) that satisfies the mean value theorem for this function and interval.

Possible Answers:

1.07

0.95

1.18

1.48

1.26

Correct answer:

1.18

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of f(x)=ln(sin(x)) on the interval (0.8,1.6)

f(0.8)=ln(sin(0.8))=-0.33

f(1.6)=ln(sin(1.6))=0

Then take the difference of the two and divide by the interval.

$\frac{0-(-0.33)}{1.6-0.8}=0.41$

Now find the derivative of the function; this will be solved for the value(s) found above.

Derivative of a natural log:

$d[ln(u)]=\frac{du}{u}$

Trigonometric derivative:

d[sin(u)]=cos(u)du

$f'(x)=\frac{cos(x)}{sin(x)}=cot(x)$

cot(x)=0.41

Using a calculator, we find the solution x=1.18 , which fits within the interval (0.8,1.6) , satisfying the mean value theorem.

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Example Question #1908 : Calculus

Let f(x)=-xln(cos(x)) on the interval (0,1.5) . Find a value for the number(s) that satisfies the mean value theorem for this function and interval.

Possible Answers:

1.07

1.44

0.21

0.73

0.12

Correct answer:

1.07

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of f(x)=-xln(cos(x)) on the interval (0,1.5)

f(0)=-(0)ln(cos(0))=0

f(1.5)=-(1.5)ln(cos(1.5))=3.97

Then take the difference of the two and divide by the interval.

$\frac{3.97-0}{1.5-0}=2.65$

Now find the derivative of the function; this will be solved for the value(s) found above.

Derivative of a natural log:

$d[ln(u)]=\frac{du}{u}$

Trigonometric derivative:

d[cos(u)]=-sin(u)du

Product rule: d[uv]=udv+vdu

$f'(x)=-ln(cos(x))-\frac{-xsin(x)}{cos(x)}=xtan(x)-ln(cos(x))$

xtan(x)-ln(cos(x))=2.65

Using a calculator, we find the solutions x=1.07 , which fits within the interval (0,1.5) , satisfying the mean value theorem.

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Example Question #1909 : Calculus

Let $f(x)=(3x^2+x)cos(2\pi x^2)$ on the interval (0,2) . Which of the following values does not satisfy the mean value theorem for this function and interval?

Possible Answers:

1.24

1.18

0.76

1.42

Correct answer:

1.18

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of $f(x)=(3x^2+x)cos(2\pi x^2)$ on the interval (0,2)

$f(0)=(3(0)^2+0)cos(2\pi (0)^2)=0$

$f(2)=(3(2)^2+(2))cos(2\pi (2)^2)=14$

Then take the difference of the two and divide by the interval.

$\frac{14-0}{2-0}=7$

Now find the derivative of the function; this will be solved for the value(s) found above.

Trigonometric derivative:

d[cos(u)]=-sin(u)du

Product rule: d[uv]=udv+vdu

$f'(x)=(6x+1)cos(2\pi x^2)-4\pi x (3x^2+x)sin(2\pi x^2)$

$(6x+1)cos(2\pi x^2)-4\pi x (3x^2+x)sin(2\pi x^2)=7$

Using a calculator, we find the solutions x=0.76,1,1.24,1.42,1.73 , which fit within the interval (0,2) , satisfying the mean value theorem.

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Example Question #1909 : Calculus

Let $f(x)=(3x^2+x)cos(2\pi x^2)$ on the interval (0,2) . Which of the following values does not satisfy the mean value theorem for this function and interval?

Possible Answers:

1.24

1.18

0.76

1.42

Correct answer:

1.18

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of $f(x)=(3x^2+x)cos(2\pi x^2)$ on the interval (0,2)

$f(0)=(3(0)^2+0)cos(2\pi (0)^2)=0$

$f(2)=(3(2)^2+(2))cos(2\pi (2)^2)=14$

Then take the difference of the two and divide by the interval.

$\frac{14-0}{2-0}=7$

Now find the derivative of the function; this will be solved for the value(s) found above.

Trigonometric derivative:

d[cos(u)]=-sin(u)du

Product rule: d[uv]=udv+vdu

$f'(x)=(6x+1)cos(2\pi x^2)-4\pi x (3x^2+x)sin(2\pi x^2)$

$(6x+1)cos(2\pi x^2)-4\pi x (3x^2+x)sin(2\pi x^2)=7$

Using a calculator, we find the solutions x=0.76,1,1.24,1.42,1.73 , which fit within the interval (0,2) , satisfying the mean value theorem.

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Example Question #881 : Differential Functions

Let f(x)=5x^4tan(x) on the interval (0,0.4) . Find a value for the number(s) that satisfies the mean value theorem for this function and interval.

Possible Answers:

0.389

0.183

0.269

-0.219

0.018

Correct answer:

0.269

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of f(x)=5x^4tan(x) on the interval (0,0.4)

f(0)=5(0)^4tan(0)=0

f(0.4)=5(0.4)^4tan(0.4)=0.0541

Then take the difference of the two and divide by the interval.

$\frac{0.0541-0}{0.4-0}=0.135$

Now find the derivative of the function; this will be solved for the value(s) found above.

Trigonometric derivative:

$d[tan(u)]=\frac{du}{cos^2(u)}$

Product Rule: d(uv)=udv+vdu

$f'(x)=20x^3tan(x)+\frac{5x^4}{cos^2(x)}$

$20x^3tan(x)+\frac{5x^4}{cos^2(x)}=0.135$

Using a calculator, we find the solution x=0.269 , which fits within the interval (0,0.4) , satisfying the mean value theorem.

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Example Question #882 : Differential Functions

Let f(x)=tan(x)tan(2x) on the interval (0,0.6) . Find a value for the number(s) that satisfies the mean value theorem for this function and interval.

Possible Answers:

0.138

0.098

0.229

0.277

0.457

Correct answer:

0.457

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of f(x)=tan(x)tan(2x) on the interval (0,0.6)

f(0)=tan(0)tan(2(0))=0

f(0.6)=tan(0.6)tan(2(0.6))=1.760

Then take the difference of the two and divide by the interval.

$\frac{1.760-0}{0.6-0}=2.933$

Now find the derivative of the function; this will be solved for the value(s) found above.

Trigonometric derivative:

$d[tan(u)]=\frac{du}{cos^2(u)}$

Product rule: d[uv]=udv+vdu

$f'(x)=\frac{tan(2x)}{cos^2(x)}+\frac{tan(x)}{cos^2(2x)}$

$\frac{tan(2x)}{cos^2(x)}+\frac{tan(x)}{cos^2(2x)}=2.933$

Using a calculator, we find the solutions x=0.457 , which fits within the interval (0,0.6) , satisfying the mean value theorem.

Report an Error

Example Question #882 : Differential Functions

Let f(x)=tan(x)tan(2x) on the interval (0,0.6) . Find a value for the number(s) that satisfies the mean value theorem for this function and interval.

Possible Answers:

0.138

0.098

0.229

0.277

0.457

Correct answer:

0.457

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of f(x)=tan(x)tan(2x) on the interval (0,0.6)

f(0)=tan(0)tan(2(0))=0

f(0.6)=tan(0.6)tan(2(0.6))=1.760

Then take the difference of the two and divide by the interval.

$\frac{1.760-0}{0.6-0}=2.933$

Now find the derivative of the function; this will be solved for the value(s) found above.

Trigonometric derivative:

$d[tan(u)]=\frac{du}{cos^2(u)}$

Product rule: d[uv]=udv+vdu

$f'(x)=\frac{tan(2x)}{cos^2(x)}+\frac{tan(x)}{cos^2(2x)}$

$\frac{tan(2x)}{cos^2(x)}+\frac{tan(x)}{cos^2(2x)}=2.933$

Using a calculator, we find the solutions x=0.457 , which fits within the interval (0,0.6) , satisfying the mean value theorem.

Report an Error

Example Question #883 : Differential Functions

Let $f(x)=\frac{x^4}{sin(x)}$ on the interval (0.5,0.9) . Find a value for the number(s) that satisfies the mean value theorem for this function and interval.

Possible Answers:

0.557

0.891

0.416

0.775

0.714

Correct answer:

0.714

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of $f(x)=\frac{x^4}{sin(x)}$ on the interval (0.5,0.9)

$f(0.5)=\frac{0.5^4}{sin(0.5)}=0.1304$

$f(0.9)=\frac{0.9^4}{sin(0.9)}=0.8376$

Then take the difference of the two and divide by the interval.

$\frac{0.8376-0.1304}{0.9-0.5}=1.768$

Now find the derivative of the function; this will be solved for the value(s) found above.

Trigonometric derivative:

d[sin(u)]=cos(u)du

Quotient Rule: $d[\frac{u}{v}]=\frac{vdu-udv}{v^2}$

$f'(x)=\frac{4x^3sin(x)-x^4cos(x)}{sin^2(x)}$

$\frac{4x^3sin(x)-x^4cos(x)}{sin^2(x)}=1.768$

Using a calculator, we find the solution x=0.714 , which fits within the interval (0.5,0.9) , satisfying the mean value theorem.

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Example Question #701 : How To Find Differential Functions

Let f(x)=ln(tan(x)) on the interval $(\frac{\pi}{4},\frac{\pi}{3})$ . Find a value for the number(s) that satisfies the mean value theorem for this function and interval.

Possible Answers:

0.633

-2.509

0.938

0.821

-2.204

Correct answer:

0.938

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.

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

Note that the value of the derivative of a function at a point is the function's slope at that point; i.e. the slope of the tangent at said point.

First, find the two function values of f(x)=ln(tan(x)) on the interval $(\frac{\pi}{4},\frac{\pi}{3})$

$f(\frac{\pi}{4})=ln(tan(\frac{\pi}{4}))=0$

$f(\frac{\pi}{3})=ln(tan(\frac{\pi}{3}))=0.549$

Then take the difference of the two and divide by the interval.

$\frac{0.549-0}{\frac{\pi}{3}-\frac{\pi}{4}}=2.097$

Now find the derivative of the function; this will be solved for the value(s) found above.

Derivative of a natural log:

$d[ln(u)]=\frac{du}{u}$

Trigonometric derivative:

$d[tan(u)]=\frac{du}{cos^2(u)}$

$f'(x)=\frac{1}{cos^2(x)tan(x)}=\frac{1}{cos(x)sin(x)}$

$\frac{1}{cos(x)sin(x)}=2.097$

Using a calculator, we find the solution x=0.938 , which fits within the interval $(\frac{\pi}{4},\frac{\pi}{3})$ , satisfying the mean value theorem.

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Calculus 1 : How to find differential functions

Study concepts, example questions & explanations for Calculus 1

All Calculus 1 Resources

Example Questions

Example Question #1901 : Calculus

Example Question #1901 : Calculus

Example Question #1908 : Calculus

Example Question #1909 : Calculus

Example Question #1909 : Calculus

Example Question #881 : Differential Functions

Example Question #882 : Differential Functions

Example Question #882 : Differential Functions

Example Question #883 : Differential Functions

Example Question #701 : How To Find Differential Functions

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