I'm currently doing some computation in Mathematica related to Quantum Mechanics. As we've moved from a 1D to 2D lattice model, the problem size is becoming problematic

Currently, we have a summation that looks something like this:

```
corr[r1_, r2_, i_, j_] = Sum[Cos[f[x1, x2] Angle[i] r1 + f[y1, y2] Angle[j] r2], {x1, HL}, {x2, HL}, {y1, HL + 1, 2 HL}, {y2, HL + 1, 2 HL}];
```

f[. , .] is a lookup function for a pre-computed correlation function, and Angle[.] is precomputed as well.

There's no way at all to simplify this further in any way. We already took a simple optimization by converting a complex exponential (which had zero imaginary part) to the cosine expression above.

The big problem is that those HL's are based on dimension size: For linear dimension L along an axis, HL corresponds to L^d (d = 2 here). So our computation is O(n^8) in reality, neglecting the sum over i, j.

This normally isn't too bad for L = 8, if it weren't for the fact that we iterate this for 125 values of r1, and 125 of r2 to create an 125 x 125 image.

My question is: How can I most efficiently calculate this in Mathematica? I would do this in another language but there are certain problems that will make it just as slow if I tried it in something like C++.

Extra info: This is a ND-ND (number density) correlation calculation. All of the x's and y's refer to discete points on a discrete 2D grid. The only non-discrete thing here is our r's.

`f`

and`Angle`

functions that have numerical definitions, or are they symbolic? Doing things numerically can make a tremendous difference. OTOH, given the size of your problem, it may be that you're just in trouble. We're talking about ~10^17 operations here. – Pillsy Jul 14 '10 at 16:20