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$\int \frac{dx}{x^2 - 2x}$

I know that I have to complete the square so the problem becomes.

$\int \frac{dx}{(x - 1)^2 -1}dx$

Then I set up my A B and C stuff

$\frac{A}{x-1} + \frac{B}{(x-1)^2} + \frac{C}{-1}$

With that I find $A = -1, B = -1$ and $C = 0$ which I know is wrong.

I must be setting up the $A, B, C$ thing wrong but I do not know why.

  • 5
    To use partial fractions, you have to factor the denominator completely and use the **factors** of the denominator. Is $(x-1)^2-1$ equal to $(x-1)^2(-1)$? No. If you are going to use partial fractions, you need to factor, and factoring here gives, either from $x^2-2x = x(x-2)$, or using difference of squares, $(x-1)^2 -1 = \Bigl((x-1)+1\Bigr)\Bigl((x-1)-1\Bigr) = x(x-2).$So if you are going to use partial fractions, you would need to set it up as $\frac{1}{x^2-2x} = \frac{A}{x} + \frac{B}{x-2},$not the mess you have.2012-06-12

4 Answers 4

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I suppose that you could have also used trigonometric substitutions. Completing the square as you have done, we get that $\displaystyle \int \frac{dx}{x^2-2x} = \int \frac{dx}{(x-1)^2 - 1}.$

We now let $x-1 = \sec \theta.$ Notice then that $dx = \tan \theta \sec \theta \ d\theta.$ We now have $ \int \frac{dx}{(x-1)^2 - 1} = \int \frac{\tan \theta \sec \theta \ d\theta}{\sec^2\theta-1} = \int \frac{\tan \theta \sec \theta \ d\theta}{\tan^2 \theta} = \int \frac{\sec \theta \ d\theta}{\tan \theta} = \int \csc \theta \ d\theta. $ And, $ \int \csc \theta \ d\theta = \ln (\csc \theta - \cot \theta) + C = \ln \left(\frac{\sqrt{x-2}}{\sqrt{x}} \right) + C,$ as desired.

(This is because from $x-1 = \sec \theta,$ we get $1/(x-1) = \cos \theta$ and thus $\sin \theta = (\sqrt{x^2-2x})/(x-1)$, and we just make the necessary substitutions in $\csc \theta - \cot \theta$).

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Added: "I know that I have to complete the square" is ambiguous. I interpreted it as meaning that the OP thought that completing the square was necessary to solve the problem.

Completing the square is not a universal tool. To find the integral efficiently, you certainly do not need to complete the square.

The simplest approach is to use partial fractions. The bottom factors as $x(x-2)$. Find numbers $A$ and $B$ such that $\frac{1}{x^2-2x}=\frac{A}{x-2}+\frac{B}{x}.$

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    @AndréNicolas : I wouldn't recomment completing the square if this appeared as a test question. But as an exercise, it's sometimes useful to learn several different ways of looking at something, and what can be learned from each.2012-06-10
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My book is telling me that I have to complete the square

$I=\begin{eqnarray*} \int \frac{dx}{x^{2}-2x} &=&\int \frac{dx}{\left( x-1\right) ^{2}-1}\overset{ u=x-1}{=}\int \frac{1}{u^{2}-1}\,du=-\text{arctanh }u+C \end{eqnarray*},$ $\tag{1}$

where I have used the substitution $u=x-1$ and the standard derivative $\frac{d}{du}\text {arctanh}=\frac{1}{1-u^{2}}\tag{2}$

You just need to substitute $u=x-1$ to write $\text{arctanh }u$ in terms of $x$.

Added 2: Remark. If we use the logarithmic representation of the inverse hyperbolic function $\text{arctanh }u$ $\begin{equation*} \text{arctanh }u=\frac{1}{2}\ln \left( u+1\right) -\frac{1}{2}\ln \left( 1-u\right),\qquad (\text{real for }|u|<1)\tag{3} \end{equation*}$ we get for $u=x−1 $ $\begin{eqnarray*} I &=&-\text{arctanh }u+C=-\text{arctanh }\left( x-1\right) +C \\ &=&-\frac{1}{2}\ln x+\frac{1}{2}\ln \left( 2-x\right) +C \\ &=&\frac{1}{2}\left( \ln \frac{2-x}{x}\right) +C\qquad (0

Added. If your book does require using partial fractions then you can proceed as follows $\begin{equation*} \int \frac{1}{u^{2}-1}\,du=\int \frac{1}{\left( u-1\right) \left( u+1\right) }\,du=\int \frac{1}{2\left( u-1\right) }-\frac{1}{2\left( u+1\right) }du. \end{equation*}$ $\tag{5}$

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$\begin{align} & {} \quad \int \frac{dx}{x^2 - 2x}\\ &=\int \frac{dx}{(x - 1)^2 -1}dx\\ &=\int \frac{dx}{(x - 1-1) (x-1+1)} \\ &=\int \frac{dx}{x(x-2)}\end{align}$

The rest is easy (partial fractions):

$\frac 12 \left[\int \frac {dx}{x-2} - \int \frac {dx}x\right]=\frac 12 \ln|x-2| -\frac 12 \ln |x| +C$

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    Done, thank you @ArturoMagidin.2012-06-12