Integrate $\int (1+\alpha^{2})^{-3/2} \sin \theta d \theta $where $\alpha = \cos \theta + a \sin \theta $ with a constant $a$.
How could I possibly do that? Trigonometrical manipulations? Or integration parts?
Integrate $\int (1+\alpha^{2})^{-3/2} \sin \theta d \theta $where $\alpha = \cos \theta + a \sin \theta $ with a constant $a$.
How could I possibly do that? Trigonometrical manipulations? Or integration parts?
Hint Making the change of variables $ \theta=\arctan(t) $ casts the integral to the form
$ \int \!{\frac {t}{ \left( 2+2\,at+({a}^{2}+1){t}^{2} \right) ^{3/2 }}}{dt}=\frac{1}{\alpha}\int \!{\frac {t}{ \left( (t+\frac{a}{\alpha})^2+\frac{a^2+2}{\alpha} \right) ^{3/2 }}}{dt}\,.$