I'm trying to integrate $e^{2x} \cdot \sin 3x dx$ using integration by parts technique. According to some websites my answer is incorrect.
My attempt was:
$\int e^{2x}\sin (3x) dx = [u=e^{2x}, du = 2e^{2x} , dv= \sin 3x, v= -1/3\cos 3x] = uv -\int vdu = -\frac{1}{3}e^{2x}\cos 3x + \frac {2}{3}\int e^{2x} \cos (3x) dx = [u=e^{2x}, du = 2e^{2x}, dv = \cos (3x), v = \frac{1}{3}\sin (3x)] = -\frac{1}{3}e^{2x} \cos3x + \frac{1}{3} e^{2x}\sin 3x -\frac{2}{3}\int e^2x \sin (3x) dx $
And so I get:
$\frac {5}{3}\int e^{2x} \sin (3x)dx = -\frac{1}{3}e^{2x}\cos 3x + \frac{1}{3}e^{2x}\sin 3x$
And finally:
$\int e^{2x} \sin (3x)dx = \frac{1}{5}e^{2x} (\sin(3x)-\cos(3x))+C$.
According to the websites I checked the answer should be $\frac{1}{13}e^{2x}(2\sin(3x)-3\cos(3x) + C$.
Where is my mistake?