(Apologies for the 'late' answer, but I have some suggestions that might help others if the existing answer doesn't help them)

It's not clear from your question how accurate the resulting function needs to be (or how big, 'big' is), but one approach that you could adopt is to regress the data points that you have using a least-squares or Kalman filter-based method. You'd need to do this with a number of candidate function forms and then choose the one that is 'best', for example by using an measure such as MAE or MSE.

Of course this requires some idea of what the form underlying function could be, but your question isn't clear as to whether you have this kind of information.

Another approach that could work (and requires no knowledge of what the underlying function might be) is the use of the fuzzy transform (F-transform) to generate line segments that provide local approximations to the surface.

The method for this would be:

- Define a 2D universe that includes the x and y domains of your input data
- Create a 2D fuzzy partition of this universe - chosing partition sizes that give the accuracy you require
- Apply the discrete F-transform using your input data to generate fuzzy data points in a 3D fuzzy space
- Pass the inverse F-transform as a function handle (along with the fuzzy data points) to your integration function

If you're not familiar with the F-transform then I posted a blog a while ago about how the F-transform can be used as a universal approximator in a 1D case: http://iainism-blogism.blogspot.co.uk/2012/01/fuzzy-wuzzy-was.html

To see the mathematics behind the method and extend it to a multidimensional case then the University of Ostravia has published a PhD thesis that explains its application to various engineering problems and also provides an example of how it is constructed for the case of a 2D universe: http://irafm.osu.cz/f/PhD_theses/Stepnicka.pdf