$$\int\frac{1}{\sqrt{ax^3+bx^2+cx+d}}dx$$
I know the solution to the integral of an inversed square root of a quadratic equation.
But I am not being able to solve this one and I have searched online to find a solution. Unfortunately I seem to have found nothing.
So help would be much appreciated.
Thank you.
As @Lubin wrote in comments, you face elliptic integrals.
The easiest way to handle them is to write $$ax^3+bx^2+cx+q=a(x-r)(x-s)(x-t)$$ where $(r,s,t)$ are the roots of the cubic equation. I let the simplifications to you
If the three roots are different the antiderivative will write $$-\frac{2 (x-r)^{3/2} \sqrt{\frac{x-s}{x-r}} \sqrt{\frac{x-t}{x-r}} }{\sqrt{s- r} \sqrt{a (x-r) (x-s) (x-t)}}\,\,F\left(\sin ^{-1}\left(\frac{\sqrt{s-r}}{\sqrt{x-r}}\right)|\frac{r-t}{r-s}\right)$$
If there is a double root $(t=s)$ $$\frac{2 \sqrt{x-r} (x-s) }{\sqrt{r-s} \sqrt{a (x-r) (x-s)^2}}\tan ^{-1}\left(\frac{\sqrt{x-r}}{\sqrt{r-s}}\right)$$ If there is a triple root $(t=s=r)$ $$-\frac{2 (x-r)}{\sqrt{a (x-r)^3}}$$