How do we solve $\int x^3\sqrt{4+x^2}dx$? I think I substituted the wrong thing in and got the wrong answer. I've tried multiple times and cant figure it out. I got that the $\sqrt{4+x^2}= 2\sec(\theta)$. Don't know what to do from there.
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1This question is tagged definite-integrals but you have not mentioned any limits of integration. Also, "I got that the square root = 2sec(theta)" doesn't make any sense. The square root of what? Please fix this, otherwise we can't help you and this question will be at risk of being closed. – Jan 31 '17 at 20:33
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I worked out what was in the square root first and got that it equals 2sec(theta) – Chris Jan 31 '17 at 20:35
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@Chris, what you really mean is that you tried a substitution, right? There is more than one possible substitution, another choice is shown in DonAntonio's answer below. A better choice, in my opinion – Yuriy S Jan 31 '17 at 20:37
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I realize that now that I could have used integration by parts instead – Chris Jan 31 '17 at 20:37
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1The irony of the title - the integral is neither tricky nor trigonometric. Although both points can be argued ;) – Yuriy S Jan 31 '17 at 20:39
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Yes you can use trig substitution here bud. And I found it tricky. – Chris Jan 31 '17 at 20:40
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@Chris That still doesn't make it a trigonometric integral... – DonAntonio Jan 31 '17 at 20:40
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Okay my bad...I hope no one got offended by this integral – Chris Jan 31 '17 at 20:42
4 Answers
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Hints: with
$$\begin{cases}u=x^2,&u'=2x\\{}\\v'=x\sqrt{4+x^2},&v=\frac13(4+x^2)^{3/2}\end{cases}\implies\int x^3\sqrt{4+x^2}\,dx=$$$${}$$
$$=\frac13x^2(4+x^2)^{3/2}-\frac23\int x(4+x^2)^{3/2}\,dx$$
DonAntonio
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$u=4+x^2\to\text{d}u=2x\text{d}x\implies \int x^3\sqrt{u}\frac{\text{d}u}{2x}$ $=\frac{1}{2}\int(4-u)u^{1/2}\text{d}u$ can you move forward from here?
Teh Rod
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Hint:
use the substitution $$ 4+x^2=t $$ that gives $$ x^3dx=\frac{1}{2}(t-4)dt $$
Emilio Novati
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$x=2\tan \theta$, we have \begin{align*} I=\int x^3\sqrt{4+x^2}dx&=16\int \tan^3\theta \sec \theta(1+\tan^2\theta) d\theta=16\int\frac{\sin^3\theta}{\cos^6\theta}d\theta\\&=16\int\frac{\sin\theta(1-\cos^2\theta)}{\cos^6\theta}d\theta \end{align*} set $\cos\theta=u$, therefore $$I=-16\int\frac{1-u^2}{u^6}du=\frac{16}{5u^5}-\frac{16}{3u^3}+c$$
Behrouz Maleki
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