You could try a `ListConvolve`

with a Gaussian kernel to smooth your data. One of the nice features of this is that the *derivative* of the **convolution** with a Gaussian kernel is equivalent to *convolving* with a **derivative** of the Gaussian kernel.

Here is some sample data:

```
data = Table[Sin[x] + .5 RandomReal[{-1, 1}], {x, 0, 6 \[Pi], .05}];
ListLinePlot[data]
```

This is a simple convolution with a Gaussian kernel:

```
data2 =
Block[{\[Sigma] = 2},
ListConvolve[
Table[1/(Sqrt[2 \[Pi]] \[Sigma]) E^(-x^2/(2 \[Sigma])),
{x, -2 , 2, 1/10}
], data, {11, 11}
]
];
ListLinePlot[data2]
```

Convolution with the first derivative of a Gaussian:

```
data3 =
Block[{\[Sigma] = 1},
ListConvolve[
Table[-((E^(-(x^2/(2 \[Sigma]))) x)/(Sqrt[2 \[Pi]] \[Sigma]^2)),
{x, -2 \[Sigma],2 \[Sigma], \[Sigma]/10}
], data, {11, 11}
]
];
ListLinePlot[data3]
```

You may want to play with the sigma parameter to see what gets optimal results in your case.

The whole theory behind this is called Scale Space. Note that the above statement about convolution holds for continuous space. For a discrete implementation, the kernel could be chosen somewhat better.

Note further that, just as MovingAverage, a convolution can move the features of your data.