For 8) once you draw the derivative f '(x) then just draw the derivative of that graph to find f ''(x).
For 12) remember that you can split an integral up into sections, for example,
\int _ 1 ^5 f(x)dx = \int _ 1 ^2 f(x)dx + \int _2 ^ 4 f(x)dx + \int _4 ^5 f(x)dx
so you should do the same, choosing your sections based on the changing slope of the graph of f.
For 15) you aren't expected to take the anti-derivative. This should be obvious because it's giving you a lot more information than just the derivative function.
So to start drawing the function, begin with points that you can quickly determine, such as f(0) = 1. Once you draw this point on your axis, also plot the limits at the ends of your graph.
Now, what can we determine from the derivative and second derivative? Well, f ''(x) has a perfect square in the denominator so it's always positive (except at x=\pm 2) and so since the numerator is -8x, this means that for positive x values, the second derivative is negative, and for negative values it's positive. This tells you what the concavity of the graph is (think of the shape of a parabola x2 that has positive concavity versus a parabola -x2 which has negative concavity).
What about the first derivative? We already know there's a problem at x=\pm 2 because the denominator is 0 at those points, so what is
\lim_{x\to 2^-} f'(x)
and
\lim_{x\to 2^+} f'(x)
and the same for -2?
