Difference between revisions of "009B Sample Final 1, Problem 7"

Revision as of 17:58, 20 May 2017

(a) Find the length of the curve

y=\ln(\cos x),~~~0\leq x\leq {\frac {\pi }{3}}

.

(b) The curve

y=1-x^{2},~~~0\leq x\leq 1

is rotated about the $y$ -axis. Find the area of the resulting surface.

Foundations:
1. The formula for the length $L$ of a curve $y=f(x)$ where $a\leq x\leq b$ is
$L=\int _{a}^{b}{\sqrt {1+{\bigg (}{\frac {dy}{dx}}{\bigg )}^{2}}}~dx.$
2. Recall
$\int \sec x~dx=\ln \|\sec(x)+\tan(x)\|+C.$
3. The surface area $S$ of a function $y=f(x)$ rotated about the $y$ -axis is given by
$S=\int 2\pi x\,ds,$ where $ds={\sqrt {1+{\bigg (}{\frac {dy}{dx}}{\bigg )}^{2}}}~dx.$

Solution:

(a)

Step 1:
First, we calculate ${\frac {dy}{dx}}.$
Since $y=\ln(\cos x),$
${\frac {dy}{dx}}={\frac {1}{\cos x}}(-\sin x)=-\tan x.$
Using the formula given in the Foundations section, we have
$L=\int _{0}^{\pi /3}{\sqrt {1+(-\tan x)^{2}}}~dx.$

Step 2:
Now, we have
${\begin{array}{rcl}L&=&\displaystyle {\int _{0}^{\pi /3}{\sqrt {1+\tan ^{2}x}}~dx}\\&&\\&=&\displaystyle {\int _{0}^{\pi /3}{\sqrt {\sec ^{2}x}}~dx}\\&&\\&=&\displaystyle {\int _{0}^{\pi /3}\sec x~dx}.\\\end{array}}$

Step 3:
Finally,
${\begin{array}{rcl}L&=&\ln \|\sec x+\tan x\|{\bigg \|}_{0}^{\frac {\pi }{3}}\\&&\\&=&\displaystyle {\ln {\bigg \|}\sec {\frac {\pi }{3}}+\tan {\frac {\pi }{3}}{\bigg \|}-\ln \|\sec 0+\tan 0\|}\\&&\\&=&\displaystyle {\ln \|2+{\sqrt {3}}\|-\ln \|1\|}\\&&\\&=&\displaystyle {\ln(2+{\sqrt {3}})}.\end{array}}$

(b)

Step 1:
We start by calculating ${\frac {dy}{dx}}.$
Since $y=1-x^{2},$
${\frac {dy}{dx}}=-2x.$
Using the formula given in the Foundations section, we have
$S\,=\,\int _{0}^{1}2\pi x{\sqrt {1+(-2x)^{2}}}~dx.$

Step 2:
Now, we have $S=\int _{0}^{1}2\pi x{\sqrt {1+4x^{2}}}~dx.$
We proceed by $u$ -substitution.
Let $u=1+4x^{2}.$
Then, $du=8xdx$ and ${\frac {du}{8}}=xdx.$
Since the integral is a definite integral, we need to change the bounds of integration.
Plugging in our values into the equation $u=1+4x^{2},$ we get
$u_{1}=1+4(0)^{2}=1$ and $u_{2}=1+4(1)^{2}=5.$
Thus, the integral becomes
${\begin{array}{rcl}S&=&\displaystyle {\int _{1}^{5}{\frac {2\pi }{8}}{\sqrt {u}}~du}\\&&\\&=&\displaystyle {{\frac {\pi }{4}}\int _{1}^{5}u^{\frac {1}{2}}~du.}\end{array}}$

Step 3:
Now, we integrate to get
${\begin{array}{rcl}\displaystyle {S}&=&\displaystyle {{\frac {\pi }{4}}{\bigg (}{\frac {2}{3}}u^{\frac {3}{2}}{\bigg )}{\bigg \|}_{1}^{5}}\\&&\\&=&\displaystyle {{\frac {\pi }{6}}u^{\frac {3}{2}}{\bigg \|}_{1}^{5}}\\&&\\&=&\displaystyle {{\frac {\pi }{6}}(5)^{\frac {3}{2}}-{\frac {\pi }{6}}(1)^{\frac {3}{2}}}\\&&\\&=&\displaystyle {{\frac {\pi }{6}}(5{\sqrt {5}}-1)}.\\\end{array}}$

Final Answer:
(a) $\ln(2+{\sqrt {3}})$
(b) ${\frac {\pi }{6}}(5{\sqrt {5}}-1)$

Return to Sample Exam

@@ Line 105: / Line 105: @@
 |Now, we have &nbsp;<math style="vertical-align: -14px">S=\int_0^{1}2\pi x \sqrt{1+4x^2}~dx.</math>
 |-
-|We proceed by using trig substitution.
+|We proceed by &nbsp;<math>u</math>-substitution.
 |-
-|Let &nbsp;<math style="vertical-align: -13px">x=\frac{1}{2}\tan \theta.</math>&nbsp; Then, &nbsp;<math style="vertical-align:  -12px">dx=\frac{1}{2}\sec^2\theta \,d\theta.</math>
+|Let &nbsp;<math style="vertical-align: -2px">u=1+4x^2.</math> &nbsp;
 |-
-|So, we have
+|Then, &nbsp; <math style="vertical-align: 0px">du=8xdx</math>&nbsp; and &nbsp;<math style="vertical-align: -14px">\frac{du}{8}=xdx.</math>
 |-
-|
+|Since the integral is a definite integral, we need to change the bounds of integration.
-&nbsp; &nbsp; &nbsp; &nbsp;<math>\begin{array}{rcl}
-\displaystyle{\int 2\pi x \sqrt{1+4x^2}~dx} & = & \displaystyle{\int 2\pi \bigg(\frac{1}{2}\tan \theta\bigg)\sqrt{1+\tan^2\theta}\bigg(\frac{1}{2}\sec^2\theta\bigg) d\theta}\\
-&&\\
-& = & \displaystyle{\int \frac{\pi}{2} \tan \theta \sec \theta \sec^2\theta d\theta}.\\
-\end{array}</math>
-|}
-{| class="mw-collapsible mw-collapsed" style = "text-align:left;"
-!Step 3: &nbsp;
 |-
-|Now, we use &nbsp;<math style="vertical-align: 0px">u</math>-substitution.
+|Plugging in our values into the equation &nbsp;<math style="vertical-align: -4px">u=1+4x^2,</math>&nbsp; we get
 |-
-|Let &nbsp;<math style="vertical-align: 0px">u=\sec \theta.</math>&nbsp; Then, &nbsp;<math style="vertical-align: -1px">du=\sec \theta \tan \theta \,d\theta.</math>
+|&nbsp; &nbsp; &nbsp; &nbsp;<math style="vertical-align: -5px">u_1=1+4(0)^2=1</math>&nbsp; and &nbsp;<math style="vertical-align: -5px">u_2=1+4(1)^2=5.</math>
 |-
-|So, the integral becomes
+|Thus, the integral becomes
 |-
 |
 &nbsp; &nbsp; &nbsp; &nbsp;<math>\begin{array}{rcl}
-\displaystyle{\int 2\pi x \sqrt{1+4x^2}~dx} & = & \displaystyle{\int \frac{\pi}{2}u^2du}\\
+S& = & \displaystyle{\int_1^5 \frac{2\pi}{8} \sqrt{u}~du}\\
 &&\\
-& = & \displaystyle{\frac{\pi}{6}u^3+C}\\
+& = & \displaystyle{\frac{\pi}{4} \int_1^5 u^{\frac{1}{2}}~du.}
-&&\\
-& = & \displaystyle{\frac{\pi}{6}\sec^3\theta+C}\\
-&&\\
-& = & \displaystyle{\frac{\pi}{6}(\sqrt{1+4x^2})^3+C}.\\
 \end{array}</math>
 |}
 {| class="mw-collapsible mw-collapsed" style = "text-align:left;"
-!Step 4: &nbsp;
+!Step 3: &nbsp;
 |-
-|We started with a definite integral. So, using Step 2 and 3, we have
+|Now, we integrate to get
 |-
 |
 &nbsp; &nbsp; &nbsp; &nbsp;<math>\begin{array}{rcl}
-S & = & \displaystyle{\int_0^1 2\pi x \sqrt{1+4x^2}~dx}\\
+\displaystyle{S} & = & \displaystyle{\frac{\pi}{4}\bigg(\frac{2}{3}u^{\frac{3}{2}}\bigg)\bigg|_{1}^{5}}\\
 &&\\
-& = & \displaystyle{\frac{\pi}{6}(\sqrt{1+4x^2})^3}\bigg|_0^1\\
+& = & \displaystyle{\frac{\pi}{6}u^{\frac{3}{2}}\bigg|_{1}^{5}}\\
 &&\\
-& = & \displaystyle{\frac{\pi(\sqrt{5})^3}{6}-\frac{\pi}{6}}\\
+& = & \displaystyle{\frac{\pi}{6}(5)^{\frac{3}{2}}-\frac{\pi}{6}(1)^{\frac{3}{2}}}\\
 &&\\
 & = & \displaystyle{\frac{\pi}{6}(5\sqrt{5}-1)}.\\

Difference between revisions of "009B Sample Final 1, Problem 7"

Revision as of 17:58, 20 May 2017

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