To find the integral in degrees, it's better - for clarity's sake, not necessarily any formal reason - to start in radians with the conversion to degrees in the sine function. That is, \sin(x^\circ) = \sin \left( \frac{\pi \; \text{radians}}{180^\circ} x^\circ\right ) ...

Area calculations using Green's theorem can go as follows, \begin{eqnarray} \text{Area} &=& \int \int dA \\ &=& \frac{1}{2} \int_{C} x dy - y dx \end{eqnarray} And take it from there.

\int \sqrt{9-x^2} dx let x=3\sin\phi,dx=3\cos\phi d\phi, thus we have 3\int d\phi\cos\phi\sqrt{9(1-sin^2\phi)}=9\int d\phi \cos^2\phi =9\int d\phi \frac{1}{2}(1+cos(2\phi))=\frac{9\phi}{2}+\frac{9\sin(2\phi)}{4}+C ...

Let \begin{align}I&= \int e^{x\sin x+\cos x}\left[\frac{x^4\cos^3 x-x\sin x+\cos x}{x^2\cos^2 x}\right]\mathrm d x\\ &= \int e^{x\sin x+\cos x}\left[\frac{\cos x - x \sin x + x^4 \cos^3 x}{x^2\cos^2x}\right]\mathrm d x\tag{1}\\ &=\int e^{x\sin x+\cos x} \left[ \frac{1}{x^2 \cos x} -\frac{\sin x}{x\cos ^2x}+x^2\cos x\right]\mathrm d x\tag{2}\\ &=\int e^{x\sin x+\cos x} \left[ \frac{1}{x^2 \cos x} -\frac{\sin x}{x\cos ^2x}+1+x^2\cos x-1\right]\mathrm dx\tag{3}\\ &=\int e^{x\sin x+\cos x} \left[ \left(\frac{1}{x^2 \cos x} -\frac{\sin x}{x\cos^2x}+1\right) +(x\cos x)\left(x-\frac{1}{x\cos x}\right)\right] \mathrm dx \tag{4} \\ \end{align} ...

Well, @Nilan has the better way to go. But, here is another "Brute Force," double substitution method that works. Write, \sin x = \sqrt{1-\cos^2 x} (the positive square root is appropriate here ...

There can't really be any general rule for choosing u and v for integration by parts but there are hierarchies that make sense most of the time. The rule I like to use for choosing u (this is ...