I'm using Mathematica 7.

I have an interpolated function, here's an example:

```
pressures =
WeatherData["Chicago", "Pressure", {2010, 8}] //
DeleteCases[#, {_, _Missing}] & //
Map[{AbsoluteTime[#[[1]]], #[[2]]} &, #] & // Interpolation;
```

I'd like to compute it's derivative, which is straight forward:

```
dpressures = D[pressures[x], x]
```

Now, If you plot this funciton

```
Plot[3600*dpressures, {x, AbsoluteTime[{2010, 8, 2}], AbsoluteTime[{2010, 8, 30}]}]
```

(sorry, don't know how to post the image from within Mathematica, and don't have time to figure it out.) You'll find that it's *very* noisy. So, I'd like to smooth it out. My first thought was to use Convolve, and integrate it against a Gaussian kernel, something like the following:

```
a = Convolve[PDF[NormalDistribution[0, 5], x], 3600*dpressures, x, y]
```

Returns

```
360 Sqrt[2/\[Pi]] Convolve[E^(-(x^2/50)), InterpolatingFunction[{{3.48961266 10^9, 3.49228746 10^9}},<>], ][x], x, y]
```

Which looks reasonable to me. Unfortunately, I believe I have made a mistake somewhere, because the result I get back does not seem to be evaluatable. That is:

```
a /. y -> AbsoluteTime[{2010, 8, 2}]
```

Returns

```
360 Sqrt[2/\[Pi]] Convolve[E^(-(x^2/50)), InterpolatingFunction[{{3.48961266 10^9, 3.49228746 10^9}},<>][x], x, 3489696000]]
```

Which just ain't what I was looking for I'm expecting a number between -1 and 1.