**ruebenko**'s answer and the comments from **user1091201** and **Leonid** together combine to give the right answers.

The **Edit 1** answer by **ruebenko** is the right first answer for *general* situations like this, that is, add the option `Method -> {"SymbolicPreprocessing", "OscillatorySelection" -> False}`

:

```
expr = (Pi*
Cos[(Pi*(-2*x + y))/(1 + y)] + (1 + y)*(-Sin[(2*Pi*x)/(1 + y)] +
Sin[(Pi*(-2*x + y))/(1 + y)]))/(E^x*(1 + y));
NIntegrate[expr, {x, 0, 100}, {y, 0, 100},
Method -> {"SymbolicPreprocessing",
"OscillatorySelection" -> False}] // AbsoluteTiming
```

And **user1091201**'s comment suggesting `Method -> "GaussKronrodRule"`

is close to the fastest possible answer for *this specific* problem.

I'll describe what is happening in NIntegrate in this specific example and along the way give some tips on handling apparently similar situations in general.

**Method Selection**

In this example, NIntegrate examines `expr`

, comes to the conclusion that multidimensional "LevinRule" is the best method for this integrand, and applies it. However, for this particular example, "LevinRule" is slower than "MultidimensionalRule" (though "LevinRule" gets a more satisfactory error estimate). "LevinRule" is also slower than any of several Gauss-type one-dimensional rules iterated over the two dimensions, such as "GaussKronrodRule" which **user1091201** found.

NIntegrate makes its decision after performing some symbolic analysis of the integrand. There are several types of symbolic pre-processing applied; the setting `Method -> {"SymbolicPreprocessing", "OscillatorySelection" -> False}`

disables one type of symbolic pre-processing.

Essentially, with "OscillatorySelection" enabled, NIntegrate selects "LevinRule". With "OscillatorySelection" disabled, NIntegrate selects "MultidimensionalRule", which is faster for this integral, although we may distrust the result based the message NIntegrate::slwcon which indicates unusually slow convergence was observed.

This is the part where Mathematica 8 differs from Mathematica 7: Mathematica 8 adds "LevinRule" and associated method selection heuristics into "OscillatorySelection".

Aside from causing NIntegrate to select a different method, disabling "OscillatorySelection" also saves the time spent doing the actual symbolic processing, which can be significant in some cases.

Setting `Method -> "GaussKronrodRule"`

overrides and skips the symbolic processing associated with method selection, and instead uses the 2-D cartesian product rule `Method -> {"CartesianRule", Method -> {"GaussKronrodRule", "GaussKronrodRule"}}`

. This happens to be a very fast method for this integral.

**Other Symbolic Processing**

Both **ruebenko**'s `Method -> {"SymbolicPreprocessing", "OscillatorySelection" -> False}`

and **user1091201**'s `Method -> "GaussKronrodRule"`

do not disable other forms of symbolic processing, and this is generally a good thing. See this part of the NIntegrate advanced documentation for a list of types of symbolic preprocessing that may be applied. In particular, "SymbolicPiecewiseSubdivision" is very valuable for integrands that are non-analytic at several points due to the presence of piecewise functions.

To disable *all* symbolic processing and get only default methods with default method options, use `Method -> {Automatic, "SymbolicProcessing" -> 0}`

. For one-dimensional integrals this currently amounts to `Method -> {"GlobalAdaptive", Method -> "GaussKronrodRule"}`

with certain default settings for all parameters of those methods (number of interpolation points in the rule, type of singularity handling for the global-adaptive strategy, etc). For multi-dimensional integrals, it currently amounts to `Method -> {"GlobalAdaptive", Method -> "MultidimensionalRule"}`

, again with certain default parameter values. For high-dimensional integrals, a monte-carlo method will be used.

I don't recommend switching straight to `Method -> {Automatic, "SymbolicProcessing" -> 0}`

as a first optimization step for NIntegrate, but it can be useful in some cases.

**Fastest method**

There is just about **always** some way to speed up a numerical integration at least a bit, sometimes a lot, since there are so many parameters that are chosen heuristically that you may benefit from tweaking. (Look at the different options and parameters that the "LevinRule" method or the "GlobalAdaptive" strategy has, including all their sub-methods etc.)

That said, here is the fastest method I found for this particular integral:

```
NIntegrate[(Pi*
Cos[(Pi*(-2*x + y))/(1 + y)] + (1 + y)*(-Sin[(2*Pi*x)/(1 + y)] +
Sin[(Pi*(-2*x + y))/(1 + y)]))/(E^x*(1 + y)), {x, 0,
100}, {y, 0, 100},
Method -> {"GlobalAdaptive", Method -> "GaussKronrodRule",
"SingularityDepth" -> Infinity}] // AbsoluteTiming
```

(The setting `"SingularityDepth" -> Infinity`

disables singularity handling transformations.)

**Integration range**

By the way, is your desired integration range really `{x, 0, 100}, {y, 0, 100}`

, or is `{x, 0, Infinity}, {y, 0, Infinity}`

the true desired integration range for your application?

If you really require `{x, 0, Infinity}, {y, 0, Infinity}`

, I suggest using that instead. For infinite-length integration ranges, NIntegrate compactifies the integrand to a finite range, effectively samples it in a geometrically-spaced way. This is usually much more efficient than linear (evenly) spaced samples that are used for finite integration ranges.