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Calculus 1 : How to find midpoint Riemann sums

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Example Questions

Example Question #151 : Differential Functions

Utilize the method of midpoint Riemann sums to approximate the average of f(x)=sin^3(x^2) over the interval (0,1.5) using three midpoints.

Possible Answers:

0.457

0.384

1.152

0.576

0.295

Correct answer:

0.384

Explanation:

To find the average of a function over a given interval of values [a,b] , the most precise method is to use an integral as follows:

$\frac{1}{b-a}\int_{a}^{b} f(x)dx$

Now for functions that are difficult or impossible to integrate,a Riemann sum can be used to approximate the value. A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length equal to the subinterval length $\frac{b-a}{n}$ , and variable heights f(x_i) , which depend on the function value at a given point x_i .

Now note that when using the method of Riemann sums to find an average value of a function, the expression changes:

$\frac{1}{b-a}\int_a^b f(x)dx \approx (\frac{1}{b-a})\frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

$\frac{1}{b-a}\int_a^b f(x)dx \approx \frac{1}{n}(f(x_1)+f(x_2)+...+f(x_n))$

We're asked to approximate the average of f(x)=sin^3(x^2) over the interval (0,1.5)

The subintervals have length $\frac{1.5-0}{3}=0.5$ , and since we are using the midpoints of each interval, the x-values are [0.25,0.75,1.25]

$\frac{1}{1.5-0}\int_{0}^{1.5}sin^3(x^2)dx\approx (\frac{1}{3})[sin^3(0.25^2)+sin^3(0.75^2)+sin^3(1.25^2)]$

$\frac{1}{1.5}\int_{0}^{1.5}sin^3(x^2)dx\approx 0.384$

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Example Question #1181 : Calculus

The derivative of an unknown function is f'(x)=tan^3(x^3) , and a function value, f(0.95)=4 , is known. Utilize the method of midpoint Riemann sums and Euler's method to approximate $\int_{1}^{1.3}f(x)dx$ using three midpoints for the former and six steps for the latter.

Possible Answers:

40.917

801.435

20.521

396.619

134.135

Correct answer:

40.917

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{1}^{1.3}f(x)dx$

So the interval is [1,1.3] , the subintervals have length $\frac{1.3-1}{3}=0.1$ , and since we are using the midpoints of each interval, the x-values are [1.05,1.15,1.25]

$\int_{1}^{1.3}f(x)dx\approx (0.1)[f(1.05)+f(1.15)+f(1.25)]$

Now, our function is unknown--we only have its derivative, f'(x)=tan^3(x^3) -- but we can calculate an approximation of function values using this derivative with Euler's method since we have an initial value, f(0.95)=4 .

Euler's method utilizes the following generalized formula

$y_{n+1}=y_n + \Delta x \cdot f'(x_n,y_n)$

or for the language used in this problem

$f(x_{n+1})=f(x_n) + \Delta x \cdot f'(x_n)$

Where $\Delta x$ is a step size. Given an intial value f(x_i) , it can in turn be used to approximate $f(x_i+\Delta x),f(x_i+2\Delta x),...,f(x_i+n\Delta x)$ , where is the number of steps taken.

To calculate this step size, consider the range of values being evaluated and the desired number of steps.

$\Delta x =\frac{1.25-0.95}{6}=0.05$

After that, it's merely a matter of taking the steps:

f(x_0)=4,x_0=0.95

f(x_1)=f(1.00)=4+(0.05)tan^3(0.95^3)=4.077

f(1.05)=4.077+(0.05)tan^3(1^3)=4.266

f(1.10)=4.266+(0.05)tan^3(1.05^3)=4.859

f(1.15)=4.859+(0.05)tan^3(1.1^3)=8.280

f(1.20)=8.280+(0.05)tan^3(1.15^3)=409.173

f(1.25)=409.173+(0.05)tan^3(1.2^3)=396.619

And from there, putting the appropriate values back into the Riemann sum approximation:

$\int_{1}^{1.3}f(x)dx\approx (0.1)[f(1.05)+f(1.15)+f(1.25)]$

$\int_{1}^{1.3}f(x)dx\approx (0.1)[4.266+8.280+396.619]$

$\int_{1}^{1.3}f(x)dx\approx 40.917$

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Example Question #151 : Functions

The derivative of an unknown function is $f'(x)=3^{cos(\frac{1}{x})}$ , and there's a known function value at f(0.5)=2 . Utilize the method of midpoint Riemann sums and Euler's method to approximate $\int_{1}^{4}f(x)dx$ using three midpoints and three steps.

Possible Answers:

11.288

7.991

13.291

6.305

15.392

Correct answer:

15.392

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{1}^{4}f(x)dx$

So the interval is [1,4] , the subintervals have length $\frac{4-1}{3}=1$ , and since we are using the midpoints of each interval, the x-values are [1.5,2.5,3.5]

$\int_{1}^{4}f(x)dx\approx (1)[f(1.5)+f(2.5)+f(3.5)]$

Now, our function is unknown--we only have its derivative $f'(x)=3^{cos(\frac{1}{x})}$ -- but we can calculate an approximation of function values using this derivative with Euler's method since we have an initial value f(0.5)=2 .

Euler's method utilizes the following generalized formula

$y_{n+1}=y_n + \Delta x \cdot f'(x_n,y_n)$

or in the case of this problem

$f(x_{n+1})=f(x_n) + \Delta x \cdot f'(x_n)$

Where $\Delta x$ is a step size. Given an intial value f(x_i) , it can in turn be used to approximate $f(x_i+\Delta x),f(x_i+2\Delta x),...,f(x_i+n\Delta x)$ , where is the number of steps taken.

To calculate this step size, consider the range of values being evaluated and the desired number of steps.

$\Delta x =\frac{3.5-0.5}{3}=1$

After that, it's merely a matter of taking the steps:

f(0.5)=2

$f(1.5)=2+(1)3^{cos(\frac{1}{0.5})}=2.633$

$f(2.5)=2.633+(1)3^{cos(\frac{1}{1.5})}=5.004$

$f(3.5)=5.004+(1)3^{cos(\frac{1}{2.5})}=7.755$

And from there, putting them back into the Riemann sum approximation:

$\int_{1}^{4}f(x)dx\approx (1)[f(1.5)+f(2.5)+f(3.5)]$

$\int_{1}^{4}f(x)dx\approx (1)[2.633+5.004+7.755]$

$\int_{1}^{4}f(x)dx\approx 15.392$

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Example Question #154 : Differential Functions

The derivative of an unknown function is $f'(x)=2^{x^2}$ , and there's a known function value at f(0.3)=5 . Utilize the method of midpoint Riemann sums and Euler's method to approximate $\int_{0.4}^{1}f(x)dx$ using three midpoints for the former and three steps for the latter.

Possible Answers:

4.862

2.204

2.889

0.869

3.279

Correct answer:

3.279

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{0.4}^{1}f(x)dx$

So the interval is [0.4,1] , the subintervals have length $\frac{1-0.4}{3}=0.2$ , and since we are using the midpoints of each interval, the x-values are [0.5,0.7,0.9]

$\int_{0.4}^{1}f(x)dx\approx (0.2)[f(0.5)+f(0.7)+f(0.9)]$

Now, our function is unknown--we only have its derivative $f'(x)=2^{x^2}$ -- but we can calculate an approximation of function values using this derivative with Euler's method since we have an initial value f(0.3)=5 .

Euler's method utilizes the following generalized formula

$y_{n+1}=y_n + \Delta x \cdot f'(x_n,y_n)$

or in the case of this problem

$f(x_{n+1})=f(x_n) + \Delta x \cdot f'(x_n)$

Where $\Delta x$ is a step size. Given an intial value f(x_i) , it can in turn be used to approximate $f(x_i+\Delta x),f(x_i+2\Delta x),...,f(x_i+n\Delta x)$ , where is the number of steps taken.

To calculate this step size, consider the range of values being evaluated and the desired number of steps.

$\Delta x =\frac{0.9-0.3}{3}=0.2$

After that, it's merely a matter of taking the steps:

f(0.3)=5

$f(0.5)=5+(0.2)2^{0.3^2}=5.213$

$f(0.7)=5.213+(0.2)2^{0.5^2}=5.451$

$f(0.9)=5.451+(0.2)2^{0.7^2}=5.732$

And from there, putting them back into the Riemann sum approximation:

$\int_{0.4}^{1}f(x)dx\approx (0.2)[f(0.5)+f(0.7)+f(0.9)]$

$\int_{0.4}^{1}f(x)dx\approx (0.2)[5.213+5.451+5.732]$

$\int_{0.4}^{1}f(x)dx\approx =3.279$

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Example Question #155 : Differential Functions

The derivative of an unknown function is , and there's a known function value at f(1)=3 . Utilize the method of midpoint Riemann sums and Euler's method to approximate $\int_{2}^{8}f(x)dx$ using three midpoints for the former and six steps for the latter.

Possible Answers:

37.232

59.017

185.206

73.614

144.205

Correct answer:

185.206

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{2}^{8}f(x)dx$

So the interval is [2,8] , the subintervals have length $\frac{8-2}{3}=2$ , and since we are using the midpoints of each interval, the x-values are [3,5,7]

$\int_{1}^{7}f(x)dx\approx (2)[f(3)+f(5)+f(7)]$

Now, our function is unknown--we only have its derivative f'(x)=ln(x^4) -- but we can calculate an approximation of function values using this derivative with Euler's method since we have an initial value f(1)=3 .

Euler's method utilizes the following generalized formula

$y_{n+1}=y_n + \Delta x \cdot f'(x_n,y_n)$

or in the case of this problem

$f(x_{n+1})=f(x_n) + \Delta x \cdot f'(x_n)$

Where $\Delta x$ is a step size. Given an intial value f(x_i) , it can in turn be used to approximate $f(x_i+\Delta x),f(x_i+2\Delta x),...,f(x_i+n\Delta x)$ , where is the number of steps taken.

To calculate this step size, consider the range of values being evaluated and the desired number of steps.

$\Delta x =\frac{7-1}{3}=2$

After that, it's merely a matter of taking the steps:

f(1)=3

f(2)=3+(2)ln(1^4)=3

f(3)=3+(2)ln(2^4)=8.545

f(4)=8.545+(2)ln(3^4)=17.334

f(5)=17.334+(2)ln(4^4)=28.424

f(6)=28.424+(2)ln(5^4)=41.300

f(7)=41.300+(2)ln(6^4)=55.634

And from there, putting them back into the Riemann sum approximation:

$\int_{1}^{7}f(x)dx\approx (2)[f(3)+f(5)+f(7)]$

$\int_{1}^{7}f(x)dx\approx (2)[8.545+28.424+55.634]$

$\int_{1}^{7}f(x)dx\approx 185.206$

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Example Question #156 : Differential Functions

The derivative of an unknown function is $f'(x)=csc(\sqrt{x})$ , and there's a known function value at f(0.5)=10 . Utilize the method of midpoint Riemann sums and Euler's method to approximate $\int_{1}^{5}f(x)dx$ using four midpoints for the former and four steps for the latter.

Possible Answers:

52.392

42.831

4.283

14.283

5.239

Correct answer:

52.392

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{1}^{5}f(x)dx$

So the interval is [1,5] , the subintervals have length $\frac{5-1}{4}=1$ , and since we are using the midpoints of each interval, the x-values are [1.5,2.5,3.5,4.5]

$\int_{1}^{5}f(x)dx\approx (1)[f(1.5)+f(2.5)+f(3.5)+f(4.5)]$

Now, our function is unknown--we only have its derivative $f'(x)=csc(\sqrt{x})$ -- but we can calculate an approximation of function values using this derivative with Euler's method since we have an initial value f(0.5)=10 .

Euler's method utilizes the following generalized formula

$y_{n+1}=y_n + \Delta x \cdot f'(x_n,y_n)$

or in the case of this problem

$f(x_{n+1})=f(x_n) + \Delta x \cdot f'(x_n)$

Where $\Delta x$ is a step size. Given an intial value f(x_i) , it can in turn be used to approximate $f(x_i+\Delta x),f(x_i+2\Delta x),...,f(x_i+n\Delta x)$ , where is the number of steps taken.

To calculate this step size, consider the range of values being evaluated and the desired number of steps.

$\Delta x =\frac{4.5-0.5}{4}=1$

After that, it's merely a matter of taking the steps:

f(0.5)=10

$f(1.5)=10+(1)csc(\sqrt{0.5})=11.539$

$f(2.5)=11.539+(1)csc(\sqrt{1.5})=12.602$

$f(3.5)=12.602+(1)csc(\sqrt{2.5})=13.602$

$f(4.5)=13.602+(1)csc(\sqrt{3.5})=14.649$

And from there, putting them back into the Riemann sum approximation:

$\int_{1}^{5}f(x)dx\approx (1)[f(1.5)+f(2.5)+f(3.5)+f(4.5)]$

$\int_{1}^{5}f(x)dx\approx (1)[11.539+12.602+13.602+14.649]$

$\int_{1}^{5}f(x)dx\approx 52.392$

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Example Question #157 : Differential Functions

The derivative of an unknown function is $f'(x)=1.5^{ln(x^3)}$ , and there's a known function value at f(1)=6 . Utilize the method of midpoint Riemann sums and Euler's method to approximate $\int_{1.5}^{5.5}f(x)dx$ using four midpoints for the former and four steps for the latter.

Possible Answers:

29.506

88.322

18.611

104.117

47.981

Correct answer:

47.981

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{1.5}^{5.5}f(x)dx$

So the interval is [1.5,5.5] , the subintervals have length $\frac{5.5-1.5}{4}=1$ , and since we are using the midpoints of each interval, the x-values are [2,3,4,5]

$\int_{1.5}^{5.5}f(x)dx\approx (1)[f(2)+f(3)+f(4)+f(5)]$

Now, our function is unknown--we only have its derivative $f'(x)=1.5^{ln(x^3)}$ -- but we can calculate an approximation of function values using this derivative with Euler's method since we have an initial value f(1)=6 .

Euler's method utilizes the following generalized formula

$y_{n+1}=y_n + \Delta x \cdot f'(x_n,y_n)$

or in the case of this problem

$f(x_{n+1})=f(x_n) + \Delta x \cdot f'(x_n)$

Where $\Delta x$ is a step size. Given an intial value f(x_i) , it can in turn be used to approximate $f(x_i+\Delta x),f(x_i+2\Delta x),...,f(x_i+n\Delta x)$ , where is the number of steps taken.

To calculate this step size, consider the range of values being evaluated and the desired number of steps.

$\Delta x =\frac{5-1}{4}=1$

After that, it's merely a matter of taking the steps:

f(1)=6

$f(2)=6+(1)1.5^{ln(1^3)}=7$

$f(3)=7+(1)1.5^{ln(2^3)}=9.324$

$f(4)=9.324+(1)1.5^{ln(3^3)}=13.129$

$f(5)=13.129+(1)1.5^{ln(4^3)}=18.528$

And from there, putting them back into the Riemann sum approximation:

$\int_{1.5}^{5.5}f(x)dx\approx (1)[f(2)+f(3)+f(4)+f(5)]$

$\int_{1.5}^{5.5}f(x)dx\approx (1)[7+9.324+13.129+18.528]$

$\int_{1.5}^{5.5}f(x)dx\approx 47.981$

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Example Question #158 : Differential Functions

Utilize the method of midpoint Riemann sums to approximate $\int_{9}^{81}1.8^{ln(\sqrt{x})}dx$ using three midpoints.

Possible Answers:

8.979

42.908

215.485

1611.708

453.220

Correct answer:

215.485

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{9}^{81}1.8^{ln(\sqrt{x})}dx$

So the interval is [9,81] , the subintervals have length $\frac{81-9}{3}=24$ , and since we are using the midpoints of each interval, the x-values are [21,45,69]

$\int_{9}^{81}1.8^{ln(\sqrt{x})}dx\approx (24)[1.8^{ln(\sqrt{21})}+1.8^{ln(\sqrt{45})}+1.8^{ln(\sqrt{69})}]$

$\int_{9}^{81}1.8^{ln(\sqrt{x})}dx\approx 215.485$

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Example Question #151 : How To Find Midpoint Riemann Sums

Utilize the method of midpoint Riemann sums to approximate $\int_{0}^{0.6}(cos(x))^{tan^2(x)}dx$ using three midpoints.

Possible Answers:

0.833

1.496

0.591

0.220

2.957

Correct answer:

0.591

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{0}^{0.6}(cos(x))^{tan^2(x)}dx$

So the interval is [0,0.6] , the subintervals have length $\frac{0.6-0}{3}=0.2$ , and since we are using the midpoints of each interval, the x-values are [0.1,0.3,0.5]

$\int_{0}^{0.6}(cos(x))^{tan^2(x)}dx\approx (0.2)[(cos(0.1))^{tan^2(0.1)}+(cos(0.3))^{tan^2(0.3)}+(cos(0.5))^{tan^2(0.5)}]$

$\int_{0}^{0.6}(cos(x))^{tan^2(x)}dx\approx 0.591$

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Example Question #151 : How To Find Midpoint Riemann Sums

Utilize the method of midpoint Riemann sums to approximate $\int_{1.5}^{16.5}(tan(x))^xdx$ using three midpoints.

Possible Answers:

$5.485 \cdot 10^{12}$

$5.485 \cdot 10^{14}$

$5.485 \cdot 10^{13}$

$5.485 \cdot 10^{15}$

$5.485 \cdot 10^{16}$

Correct answer:

$5.485 \cdot 10^{12}$

Explanation:

A Riemann sum integral approximation over an interval [a,b] with subintervals follows the form:

$\int_a^b f(x)dx \approx \frac{b-a}{n}(f(x_1)+f(x_2)+...+f(x_n))$

It is essentially a sum of rectangles each with a base of length $\frac{b-a}{n}$ and variable heights f(x_i) , which depend on the function value at a given point x_i .

We're asked to approximate $\int_{1.5}^{16.5}(tan(x))^xdx$

So the interval is [1.5,16.5] , the subintervals have length $\frac{16.5-1.5}{3}=5$ , and since we are using the midpoints of each interval, the x-values are [4,9,14]

$\int_{1.5}^{16.5}(tan(x))^{x}dx\approx (5)[(tan(4))^{4}+(tan(9))^{9}+(tan(14))^{14}]$

$\int_{1.5}^{16.5}(tan(x))^{x}dx\approx 5.485 \cdot 10^{12}$

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Calculus 1 : How to find midpoint Riemann sums

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Example Question #151 : Differential Functions

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Example Question #151 : How To Find Midpoint Riemann Sums

Example Question #151 : How To Find Midpoint Riemann Sums

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