Integrate $$I=\int\frac{\cos^2x}{1+\tan x}dx$$
$$I=\int\frac{\cos^3xdx}{\cos x+\sin x}=\int\frac{\cos^3x(\cos x-\sin x)dx}{\cos^2x-\sin^2x}=\int\frac{\cos^4xdx}{1-2\sin^2x}-\int\frac{\cos^3x\sin xdx}{2\cos^2x-1}$$ Let $t=\sin x,u=\cos x,dt=\cos xdx,du=-\sin xdx$ $$I=\underbrace{\int\frac{-u^4du}{(2u^2-1)\sqrt{1-u^2}}}_{I_1}+\underbrace{\int\frac{u^3du}{2u^2-1}}_{I_2}$$ I have found(using long division): $$I_2=\frac{u^2}2+\frac18\ln|2u^2-1|+c=\frac12\cos^2x+\frac18\ln|\cos2x|$$ I have converted $I_1$ into this: $$I_1=\frac12\left(\int(-2)\sqrt{1-u^2}du+\int\frac{du}{\sqrt{1-u^2}}\right)+\frac14\underbrace{\int\frac{du}{(2u^2-1)\sqrt{1-u^2}}}_{I_3}$$ Now I have took $v=1/u$ in $I_3$ so that $du=-(1/v^2)dv$: $$I_3=\int\frac{vdv}{(v^2-2)\sqrt{v^2-1}}$$ Now I took $w^2=v^2-1$ or $wdw=vdv$ to get: $$I_3=\int\frac{dw}{w^2-1}=\frac12\ln\left|\frac{w-1}{w+1}\right|$$ I have not yet formulated the entire thing;
- Is this correct?
- This is very long, do you have any "shorter" method?