$$\int^{ }_{} \frac{1}{1+\alpha \csc^2(x)}dx=\int \frac{\csc^2(x)}{\csc^2(x)+\alpha \csc^4(x)}dx$$
and $$\csc^2(x)=\cot^2(x)+1$$
$\int \frac{\cot^2 (x) +1}{\cot^2 (x)+1+\alpha (\cot^2 (x) +1)^2}dx$
$\int \frac{\csc^2x}{\cot^2 (x)+1+\alpha (\cot^2 (x) +1)^2}dx$
Then substitute $t=\cot(x)=> dt = -\csc^2 x \,dx.$
$\int \frac{-dt}{t^2 +1+\alpha (t^2 +1)^2}$
$\int \frac{-dt}{(t^2 +1)(1+\alpha (t^2 +1))}$
$\int (\frac {\alpha}{(\alpha t^2 + \alpha + 1)} -\frac{ 1}{(t^2 + 1)})dt$
$\int \frac {\alpha}{(\alpha t^2 + \alpha + 1)}dt - \int \frac{ 1}{(t^2 + 1)}dt$
$ \int \frac {\alpha}{(\alpha t^2 + \alpha + 1)}dt=\frac{\alpha}{\alpha+1}\int \frac {1}{1+\frac{\alpha t^2}{\alpha+1}}dt\,\,\,\,\,$
[substitute $u=t\sqrt{\frac{\alpha}{\alpha+1}}] $
$=\frac{\alpha}{\alpha+1}[\sqrt{\frac{\alpha}{\alpha+1}}+\frac{\sqrt{\frac{\alpha}{\alpha+1}}}{a}]\int \frac {1}{u^2+1}du=\frac{\alpha}{\alpha+1}[\sqrt{\frac{\alpha}{\alpha+1}}+\frac{\sqrt{\frac{\alpha}{\alpha+1}}}{a}]\tan^{-1}(t\sqrt{\frac{\alpha}{\alpha+1}})$
$\int \frac {\alpha}{(\alpha t^2 + \alpha + 1)}dt - \int \frac{ 1}{(t^2 + 1)}dt=\frac{\alpha}{\alpha+1}[\sqrt{\frac{\alpha}{\alpha+1}}+\frac{\sqrt{\frac{\alpha}{\alpha+1}}}{a}]\tan^{-1}(t\sqrt{\frac{\alpha}{\alpha+1}})-\tan^{-1}t$
$$=(\frac{\sqrt {a}}{\sqrt{\alpha+1}})\tan^{-1}(\cot (x)\sqrt{\frac{\alpha}{\alpha+1}})-\tan^{-1} (\cot x)+C$$