Difference between revisions of "Math 22 Integration by Parts and Present Value"

Latest revision as of 16:22, 3 September 2020

Integration by Parts

 Let  $u$  and  $v$  be differentiable functions of  $x$ .
 
  $\int udv=uv-\int vdu$

Exercises Use integration by parts to evaluation:

1) $\int \ln xdx$

Solution:
Let $u=\ln x$ , $>du={\frac {1}{x}}dx$
and $dv=dx$ and $v=x$
Then, by integration by parts: $\int \ln xdx=x\ln x-\int x{\frac {1}{x}}dx=x\ln x-\int dx=x\ln x-x+C$

2) $\int xe^{3x}dx$

Solution:
Let $u=x$ , $du=dx$
and $dv=e^{3x}dx$ and $v={\frac {1}{3}}e^{3x}$
Then, by integration by parts: $\int xe^{3x}dx=x{\frac {1}{3}}e^{3x}-\int {\frac {1}{3}}e^{3x}dx=x{\frac {1}{3}}e^{3x}-{\frac {1}{9}}e^{3x}+C$

3) $\int x^{2}e^{-x}dx$

Solution:
Let $u=x^{2}$ , $du=2xdx$
and $dv=e^{-x}dx$ and $v=-e^{-x}$
Then, by integration by parts: $\int x^{2}e^{-x}dx=x^{2}(-e^{-x})-\int -e^{-x}2xdx=-x^{2}e^{-x}+\int 2xe^{-x}dx$
Now, we apply integration by parts the second time for $\int 2xe^{-x}dx$
Let $u=2x$ , $du=2dx$
and $dv=e^{-x}dx$ and $v=-e^{-x}$
So $\int 2xe^{-x}dx=2x(-e^{-x})-\int -e^{-x}2dx=-2xe^{-x}-e^{-x}+C$
Therefore, $\int x^{2}e^{-x}dx=-x^{2}e^{-x}-2xe^{-x}-e^{-x}+C$

Note

1. Tabular integration technique (look it up) is convenient in some cases.

Return to Topics Page

This page were made by Tri Phan

@@ Line 1: / Line 1: @@
+==Integration by Parts==
+  Let <math>u</math> and <math>v</math> be differentiable functions of <math>x</math>.
+  <math>\int u dv=uv-\int v du</math>
+'''Exercises''' Use integration by parts to evaluation:
+'''1)''' <math>\int \ln x dx</math>
+{| class = "mw-collapsible mw-collapsed" style = "text-align:left;"
+!Solution: &nbsp;
+|-
+|Let <math>u=\ln x</math>, <math>>du=\frac{1}{x}dx</math>
+|-
+|and <math>dv=dx</math> and <math>v=x</math>
+|-
+|Then, by integration by parts: <math>\int \ln x dx=x\ln x-\int x\frac{1}{x}dx=x\ln x-\int dx=x\ln x -x +C</math>
+|}
+'''2)''' <math>\int xe^{3x}dx</math>
+{| class = "mw-collapsible mw-collapsed" style = "text-align:left;"
+!Solution: &nbsp;
+|-
+|Let <math>u=x</math>, <math>du=dx</math>
+|-
+|and <math>dv=e^{3x}dx</math> and <math>v=\frac{1}{3}e^{3x}</math>
+|-
+|Then, by integration by parts: <math>\int xe^{3x}dx=x\frac{1}{3}e^{3x} -\int\frac{1}{3}e^{3x} dx=x\frac{1}{3}e^{3x}-\frac{1}{9}e^{3x} +C </math>
+|}
+'''3)''' <math>\int x^2e^{-x}dx</math>
+{| class = "mw-collapsible mw-collapsed" style = "text-align:left;"
+!Solution: &nbsp;
+|-
+|Let <math>u=x^2</math>, <math>du=2xdx</math>
+|-
+|and <math>dv=e^{-x}dx</math> and <math>v=-e^{-x}</math>
+|-
+|Then, by integration by parts: <math>\int x^2e^{-x}dx=x^2(-e^{-x}) -\int-e^{-x}2x dx=-x^2e^{-x}+\int 2xe^{-x}dx </math>
+|-
+|Now, we apply integration by parts the second time for <math>\int 2xe^{-x}dx</math>
+|-
+|Let <math>u=2x</math>, <math>du=2dx</math>
+|-
+|and <math>dv=e^{-x}dx</math> and <math>v=-e^{-x}</math>
+|-
+|So <math>\int 2xe^{-x}dx=2x(-e^{-x})-\int -e^{-x} 2dx=-2xe^{-x}-e^{-x}+C</math>
+|-
+|Therefore, <math>\int x^2e^{-x}dx=-x^2e^{-x}-2xe^{-x}-e^{-x}+C</math>
+|}
+==Note==
+. Tabular integration technique (look it up) is convenient in some cases.
 [[Math_22| '''Return to Topics Page''']]
 '''This page were made by [[Contributors|Tri Phan]]'''

Difference between revisions of "Math 22 Integration by Parts and Present Value"

Latest revision as of 16:22, 3 September 2020

Integration by Parts

Note

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