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I was trying to calculate

$\int\frac{x^3}{\sqrt{4+x^2}}$

Doing $x = 2\tan(\theta)$, $dx = 2\sec^2(\theta)~d\theta$, $-\pi/2 < 0 < \pi/2$ I have:

$\int\frac{\left(2\tan(\theta)\right)^3\cdot2\cdot\sec^2(\theta)~d\theta}{2\sec(\theta)}$

which is

$8\int\tan(\theta)\cdot\tan^2(\theta)\cdot\sec(\theta)~d\theta$

now I got stuck ... any clues what's the next substitution to do? I'm sorry for the formatting. Could someone please help me with the formatting?

3 Answers 3

7

You have not chosen an efficient way to proceed. However, let us continue along that path.

Note that $\tan^2\theta=\sec^2\theta-1$. So you want $\int 8(\sec^2\theta -1)\sec\theta\tan\theta\,d\theta.$ Let $u=\sec\theta$.

Remark: My favourite substitution for this problem and close relatives is a variant of the one used by Ayman Hourieh. Let $x^2+4=u^2$. Then $2x\,dx=2u\,du$, and $x^2=u^2-4$. So $\int \frac{x^3}{\sqrt{x^2+4}}\,dx=\int \frac{(u^2-4)u}{u}\,du=\int (u^2-4)\,du.$

6

Let $u = x^2 + 4$, $du = 2x\,dx$:

\begin{align*} I &= \frac{1}{2} \int \frac{u - 4}{\sqrt{u}}du \end{align*}

Should be easy to take it from there.

  • 1
    @philippe You mean $2\tan(x)$? First, it's advisable to use a different variable when doing variable substitution. Second, I think you'll end up doing another substitution similar to mine if you insist on switching to $2\tan(x)$ first.2012-09-16
4

HINT: $\tan^2\theta=\sec^2\theta-1$, and $d(\sec\theta)=\sec\theta\tan\theta~d\theta$.