# Mathematica integrating over set of points to get analytical form of function

I have a following problem - I need to integrate such a function in Mathematica (I couldn't post an image, so I am writing it in latex form):

G(r)= \int_{0}^{\infty} dq f(q)*q*sin(qr)/r

To obtain funtion G(r) dependable on r. Nevertheless I don't know the analytical form of f(q), instead I have set of values of f(q) and for q. So I'd like to make a some kind of numerical integration, but to receive not a value afterwards, but a curve of G(r). I hope to get some help.
Cheers!

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@JohnDean If you have more questions about Mathematica it will be better if you ask your questions at this site : mathematica.stackexchange.com because it is specifically for Mathematica users. –  Artes May 15 '12 at 23:10

In case you know the analytic form of the function f[q] you can do this :

Integrate[f[q] q Sin[q r]/r, {q, 0, Infinity}]


but in case of knowing only values of f[q] you can integrate numerically :

G[r_]:= NIntegrate[ f[q] q Sin[q r]/r, {q, 0, Infinity}]


Assume e.g.

f[q_] := Exp[-q]
Integrate[f[q] q Sin[q r]/r, {q, 0, Infinity}]


yields

ConditionalExpression[2/(1 + r^2)^2, Abs[Im[r]] < 1]


You can make an assumption a priori, e.g. :

Assuming[r > 0, Integrate[f[q] q Sin[q r]/r, {q, 0, Infinity}]]


yields

2/(1 + r^2)^2


Assuming r > 0 you implicitly assume r to be real, so Im[r] == 0. Having the function G[r] we can plot the appropriate curve, defining f[q] as above :

Plot[ G[r], {r, 0, 10}]


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Thanks for such a quick answer. Nevertheless I've some comments - I can't assume any kind of a function, because there is no analytical form of f(q). I know the shape of it as its values are data points from an experiment. –  John Dean May 16 '12 at 14:34
But I have some other idea - I'd just make a loop for numerical integration for discrete r values and in the end getting discrete form of G(r). But there arises other problem, when I want to make just a numerical integration with my data points, as you have written in second code, I get set of values, not an area under the curve. I don't know why. –  John Dean May 16 '12 at 14:42
Assuming was here only an example how one can refine ConditionalExpression. If you know values of f[q] you can use NIntegrate. –  Artes May 16 '12 at 14:42
Maybe use your (q,f(q) known values to create an InterpolatingFunction for f. Then use that in the numeric integration that defines G[r] for numeric r. –  Daniel Lichtblau May 17 '12 at 14:55