\displaystyle{\int_{{0}}^{\infty}}{x}{\left({1}+{x}^{{2}}\right)}^{{-{{2}}}}{\left.{d}{x}\right.}=\frac{{1}}{{2}} Explanation: Evaluate first the indefinite integral: \displaystyle{F}{\left({x}\right)}=\int{x}{\left({1}+{x}^{{2}}\right)}^{{-{{2}}}}{\left.{d}{x}\right.} ...

Use substitution. Explanation: \displaystyle\int{x}{\left({1}-{3}{x}^{{2}}\right)}^{{4}}{\left.{d}{x}\right.} Set \displaystyle{u}={1}-{3}{x}^{{2}} . Then \displaystyle{d}{u}=-{6}{x}{\left.{d}{x}\right.} ...

You can, just make sure you have a +C because logs and complex numbers are ugly wrt branch cuts. What you wrote is another form of \tan^{-1}(x). In general though, logs and complex numbers ...

You are integrating with respect to x, not (1+x^2). It is why it doesn't work the way you think. U-substitution makes this possible. So in a way it is kind of what you expect. Just a little ...

Added: I interpreted the question as follows: suppose that we use the integration by parts formula, \int u(x)v'(x)\,dx = u(x)v(x) - \int v(x)u'(x)\,dx and \int v(x)u'(x)\,dx = \alpha \int u(x)v'(x)\,dx ...

Substitute x=\tan{t}. Then, \int_0^\infty \frac{dx}{(x^2+1)^4} dx=\int_0^\frac{\pi}{2} \cos^6{t} dt=\int_0^{\frac{\pi}{2}} (\frac{1+\cos{2t}}{2})^3 dt. By repeated use of formula \cos^2{t}=\frac{1+\cos{2t}}{2} ...