Difference between revisions of "022 Exam 2 Sample A, Problem 3"

Latest revision as of 06:47, 16 May 2015

Find the antiderivative of $\int {\frac {1}{3x+2}}\,dx.$

Foundations:
This problem requires two rules of integration. In particular, you need
Integration by substitution (u - sub): If $u=g(x)$ is a differentiable functions whose range is in the domain of $f$ , then
$\int g'(x)f(g(x))dx\,=\,\int f(u)du.$
We also need the derivative of the natural log since we will recover natural log from integration:
$\left(ln(x)\right)'\,=\,{\frac {1}{x}}.$

Solution:

Step 1:
Use a u-substitution with $u=3x+2.$ This means $du=3\,dx$ , or $dx=du/3$ . After substitution we have $\int {\frac {1}{3x+2}}\,dx\,=\,\int {\frac {1}{u}}\,{\frac {du}{3}}\,=\,{\frac {1}{3}}\int {\frac {1}{u}}\,du.$

Step 2:
We can now take the integral remembering the special rule resulting in natural log:
${\frac {1}{3}}\int {\frac {1}{u}}\,du\,=\,{\frac {\log(u)}{3}}.$

Step 3:
Now we need to substitute back into our original variables using our original substitution $u=3x+2$ to find
${\frac {\log(u)}{3}}={\frac {\log(3x+2)}{3}}.$

Step 4:
Since this integral is an indefinite integral, we have to remember to add a constant $C$ at the end.

Final Answer:
$\int {\frac {1}{3x+2}}\,dx\,=\,{\frac {\ln(3x+2)}{3}}+C.$

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 !Step 2: &nbsp;
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-|We can now take the integral remembering the special rule:
+|We can now take the integral remembering the special rule resulting in natural log:
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 !Step 3: &nbsp;
 |-
-| Now we need to substitute back into our original variables using our original substitution <math style="vertical-align: -5%">u = 3x + 2</math>
+| Now we need to substitute back into our original variables using our original substitution <math style="vertical-align: -5%">u = 3x + 2</math> to find
 |-
-| to find&nbsp; <math>\frac{\log(u)}{3} = \frac{\log(3x + 2)}{3}.</math>
+|
+::<math>\frac{\log(u)}{3} = \frac{\log(3x + 2)}{3}.</math>
 |}