Difference between revisions of "009B Sample Final 1, Problem 5"

Revision as of 08:45, 10 April 2017

The region bounded by the parabola $y=x^{2}$ and the line $y=2x$ in the first quadrant is revolved about the $y$ -axis to generate a solid.

(a) Sketch the region bounded by the given functions and find their points of intersection.

(b) Set up the integral for the volume of the solid.

(c) Find the volume of the solid by computing the integral.

Foundations:
1. You can find the intersection points of two functions, say $f(x),g(x),$
by setting $f(x)=g(x)$ and solving for $x.$
2. The volume of a solid obtained by rotating an area around the $y$ -axis using cylindrical shells is given by
$\int 2\pi rh~dx,$ where $r$ is the radius of the shells and $h$ is the height of the shells.

Solution:

(a)

Step 1:
First, we sketch the region bounded by the given functions.
Insert graph here.

Step 2:
Setting the equations equal, we have $x^{2}=2x.$
Solving for $x,$ we get
${\begin{array}{rcl}\displaystyle {0}&=&\displaystyle {x^{2}-2x}\\&&\\&=&\displaystyle {x(x-2).}\end{array}}$
So, $x=0$ and $x=2.$
If we plug these values into our functions, we get the intersection points
$(0,0)$ and $(2,4).$
This intersection points can be seen in the graph shown in Step 1.

(b)

Step 1:
We proceed using cylindrical shells. The radius of the shells is given by $r=x.$
The height of the shells is given by $h=2x-x^{2}.$

Step 2:
So, the volume of the solid is
$\int 2\pi rh~dx~=~\int _{0}^{2}2\pi x(2x-x^{2})~dx.$

(c)

Step 1:
We need to integrate
$\int _{0}^{2}2\pi x(2x-x^{2})~dx~=~2\pi \int _{0}^{2}2x^{2}-x^{3}~dx.$

Step 2:
We have
${\begin{array}{rcl}\displaystyle {\int _{0}^{2}2\pi x(2x-x^{2})~dx}&=&\displaystyle {2\pi \int _{0}^{2}2x^{2}-x^{3}~dx}\\&&\\&=&\displaystyle {2\pi {\bigg (}{\frac {2x^{3}}{3}}-{\frac {x^{4}}{4}}{\bigg )}{\bigg \|}_{0}^{2}}\\&&\\&=&\displaystyle {2\pi {\bigg (}{\frac {2^{4}}{3}}-{\frac {2^{4}}{4}}{\bigg )}-2\pi (0)}\\&&\\&=&\displaystyle {{\frac {8\pi }{3}}.}\\\end{array}}$

Final Answer:
(a) $(0,0),(2,4)$ (See Step 1 for the graph)
(b) $\int _{0}^{2}2\pi x(2x-x^{2})~dx$
(c) ${\frac {8\pi }{3}}$

Return to Sample Exam

@@ Line 1: / Line 1: @@
-<span class="exam"> Consider the solid obtained by rotating the area bounded by the following three functions about the <math style="vertical-align: -3px">y</math>-axis:
+<span class="exam"> The region bounded by the parabola &nbsp;<math style="vertical-align: -4px">y=x^2</math>&nbsp; and the line &nbsp;<math style="vertical-align: -4px">y=2x</math>&nbsp; in the first quadrant is revolved about the &nbsp;<math style="vertical-align: -4px">y</math>-axis to generate a solid.
-::::::<span class="exam"> <math style="vertical-align: 0px">x=0</math>, <math style="vertical-align: -4px">y=e^x</math>, and <math style="vertical-align: -4px">y=ex</math>.
+<span class="exam">(a) Sketch the region bounded by the given functions and find their points of intersection.
-::<span class="exam">a) Sketch the region bounded by the given three functions. Find the intersection point of the two functions:
+<span class="exam">(b) Set up the integral for the volume of the solid.
-::::::<span class="exam"><math style="vertical-align: -4px">y=e^x</math> and <math style="vertical-align: -4px">y=ex</math>. (There is only one.)
+<span class="exam">(c) Find the volume of the solid by computing the integral.
-::<span class="exam">b) Set up the integral for the volume of the solid.
-::<span class="exam">c) Find the volume of the solid by computing the integral.
 {| class="mw-collapsible mw-collapsed" style = "text-align:left;"
 !Foundations: &nbsp;
 |-
-|Recall:
+|'''1.''' You can find the intersection points of two functions, say &nbsp; <math style="vertical-align: -5px">f(x),g(x),</math>
 |-
 |
-::'''1.''' You can find the intersection points of two functions, say <math style="vertical-align: -5px">f(x),g(x),</math>
+&nbsp; &nbsp; &nbsp; &nbsp; by setting &nbsp;<math style="vertical-align: -5px">f(x)=g(x)</math>&nbsp; and solving for &nbsp;<math style="vertical-align: 0px">x.</math>
 |-
-|
+|'''2.''' The volume of a solid obtained by rotating an area around the &nbsp;<math style="vertical-align: -4px">y</math>-axis using cylindrical shells is given by
-:::by setting <math style="vertical-align: -5px">f(x)=g(x)</math> and solving for <math style="vertical-align: 0px">x.</math>
 |-
 |
-::'''2.''' The volume of a solid obtained by rotating an area around the <math style="vertical-align: -4px">y</math>-axis using cylindrical shells is given by
+&nbsp; &nbsp; &nbsp; &nbsp; <math style="vertical-align: -13px">\int 2\pi rh~dx,</math>&nbsp; where &nbsp;<math style="vertical-align: 0px">r</math>&nbsp; is the radius of the shells and &nbsp;<math style="vertical-align: 0px">h</math>&nbsp; is the height of the shells.
-|-
-|
-:::<math style="vertical-align: -13px">\int 2\pi rh~dx,</math> where <math style="vertical-align: 0px">r</math> is the radius of the shells and <math style="vertical-align: 0px">h</math> is the height of the shells.
 |}
 '''Solution:'''
@@ Line 36: / Line 29: @@
 !Step 1: &nbsp;
 |-
-|First, we sketch the region bounded by the three functions.  The region is shown in red, while the revolved solid is shown in blue.
+|First, we sketch the region bounded by the given functions.
-|-
-|&nbsp;
 |-
-|[[File:9BF1 5 GP.png|center|500px]]
+|Insert graph here.
 |}
@@ Line 46: / Line 37: @@
 !Step 2: &nbsp;
 |-
-|Setting the equations equal, we have <math style="vertical-align: 0px">e^x=ex.</math>
+|Setting the equations equal, we have &nbsp;<math style="vertical-align: 0px">x^2=2x.</math>
+|-
+|Solving for &nbsp;<math style="vertical-align: -4px">x,</math>&nbsp; we get
+|-
+|&nbsp; &nbsp; &nbsp; &nbsp;<math>\begin{array}{rcl}
+\displaystyle{0} & = & \displaystyle{x^2-2x}\\
+&&\\
+& = & \displaystyle{x(x-2).}
+\end{array}</math>
 |-
-|We get one intersection point, which is <math style="vertical-align: -4px">(1,e).</math>
+|So, &nbsp;<math style="vertical-align: 0px">x=0</math>&nbsp; and &nbsp;<math style="vertical-align: 0px">x=2.</math>
 |-
-|This intersection point can be seen in the graph shown in Step 1.
+|If we plug these values into our functions, we get the intersection points
+|-
+|&nbsp; &nbsp; &nbsp; &nbsp;<math style="vertical-align: -4px">(0,0)</math>&nbsp; and &nbsp;<math style="vertical-align: -4px">(2,4).</math>
+|-
+|This intersection points can be seen in the graph shown in Step 1.
 |}
@@ Line 58: / Line 61: @@
 !Step 1: &nbsp;
 |-
-|We proceed using cylindrical shells. The radius of the shells is given by <math style="vertical-align: 0px">r=x.</math>
+|We proceed using cylindrical shells. The radius of the shells is given by &nbsp;<math style="vertical-align: 0px">r=x.</math>
 |-
-|The height of the shells is given by
+|The height of the shells is given by &nbsp;<math style="vertical-align: 0px">h=2x-x^2.</math>
-|-
-|
-::<math style="vertical-align: 0px">h=e^x-ex.</math>
 |}
@@ Line 72: / Line 72: @@
 |-
 |
-::<math style="vertical-align: -14px">\int 2\pi rh\,dx\,=\,\int_0^1 2\pi x(e^x-ex)\,dx.</math>
+&nbsp; &nbsp; &nbsp; &nbsp;<math style="vertical-align: -14px">\int 2\pi rh~dx~=~\int_0^2 2\pi x(2x-x^2)~dx.</math>
 |}
@@ Line 83: / Line 83: @@
 |-
 |
-::<math>\int_0^1 2\pi x(e^x-ex)\,dx\,=\,2\pi\int_0^1 xe^x\,dx-2\pi\int_0^1ex^2\,dx.</math>
+&nbsp; &nbsp; &nbsp; &nbsp; <math>\int_0^2 2\pi x(2x-x^2)~dx~=~2\pi\int_0^2 2x^2-x^3~dx.</math>
 |}
@@ Line 89: / Line 89: @@
 !Step 2: &nbsp;
 |-
-|For the first integral, we need to use integration by parts.
+|We have
-|-
-|Let <math style="vertical-align: 0px">u=x</math> and <math style="vertical-align: 0px">dv=e^xdx.</math> Then, <math style="vertical-align: 0px">du=dx</math> and <math style="vertical-align: 0px">v=e^x.</math>
-|-
-|So, the integral becomes
 |-
 |
-::<math>\begin{array}{rcl}
+&nbsp; &nbsp; &nbsp; &nbsp;<math>\begin{array}{rcl}
-\displaystyle{\int_0^1 2\pi x(e^x-ex)~dx} & = & \displaystyle{2\pi\bigg(xe^x\bigg|_0^1 -\int_0^1 e^xdx\bigg)-\frac{2\pi ex^3}{3}\bigg|_0^1}\\
+\displaystyle{\int_0^2 2\pi x(2x-x^2)~dx} & = & \displaystyle{2\pi\int_0^2 2x^2-x^3~dx}\\
 &&\\
-& = & \displaystyle{2\pi\bigg(xe^x-e^x\bigg)\bigg|_0^1-\frac{2\pi e}{3}}\\
+& = & \displaystyle{2\pi\bigg(\frac{2x^3}{3}-\frac{x^4}{4}\bigg)\bigg|_0^2}\\
 &&\\
-& = & \displaystyle{2\pi(e-e-(-1))-\frac{2\pi e}{3}}\\
+& = & \displaystyle{2\pi\bigg(\frac{2^4}{3}-\frac{2^4}{4}\bigg)-2\pi(0)}\\
 &&\\
-& = & \displaystyle{2\pi-\frac{2\pi e}{3}}.\\
+& = & \displaystyle{\frac{8\pi}{3}.}\\
 \end{array}</math>
 |}
 {| class="mw-collapsible mw-collapsed" style = "text-align:left;"
 !Final Answer: &nbsp;
 |-
-|&nbsp;&nbsp; '''(a)''' &nbsp;<math style="vertical-align: -5px">(1,e)</math> (See Step 1 for the graph)
+|&nbsp; &nbsp;'''(a)''' &nbsp; &nbsp;<math style="vertical-align: -5px">(0,0),(2,4)</math>&nbsp; (See Step 1 for the graph)
 |-
-|&nbsp;&nbsp; '''(b)''' &nbsp;<math style="vertical-align: -15px">\int_0^1 2\pi x(e^x-ex)~dx</math>
+|&nbsp; &nbsp;'''(b)''' &nbsp; &nbsp;<math style="vertical-align: -15px">\int_0^2 2\pi x(2x-x^2)~dx</math>
 |-
-|&nbsp;&nbsp; '''(c)''' &nbsp;<math style="vertical-align: -14px">2\pi-\frac{2\pi e}{3}</math>
+|&nbsp; &nbsp;'''(c)''' &nbsp; &nbsp;<math style="vertical-align: -14px">\frac{8\pi}{3}</math>
 |}
 [[009B_Sample_Final_1|'''<u>Return to Sample Exam</u>''']]

Difference between revisions of "009B Sample Final 1, Problem 5"

Revision as of 08:45, 10 April 2017

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