## First step : What kind of audio filter do you need ?

### Choose the filtered band

For the following steps, i assume you need a **Low-pass Filter**.

### Choose your cutoff frequency

The Cutoff frequency is the frequency where your signal will be attenuated by -3dB.

Your example signal is 440Hz, so let's choose a Cutoff frequency of **400Hz**. Then your 440Hz-signal is attenuated (more than -3dB), by the Low-pass 400Hz filter.

### Choose your filter type

According to this other stackoverflow answer

Filter design is beyond the scope of Stack Overflow - that's a DSP
problem, not a programming problem. Filter design is covered by any
DSP textbook - go to your library. I like Proakis and Manolakis'
Digital Signal Processing. (Ifeachor and Jervis' Digital Signal
Processing isn't bad either.)

To go inside a simple example, I suggest to use a **moving average** filter (for a simple low-pass filter).

See Moving average

Mathematically, a moving average is a type of convolution and so it can be viewed as an example of a low-pass filter used in signal processing

This Moving average Low-pass Filter is a basic filter, and it is quite easy to use and to understand.

The parameter of the moving average is the **window length**.

The relationship between moving average window length and Cutoff frequency needs little bit mathematics and is explained here

The code will be

```
import math
sampleRate = 11025.0
cutOffFrequency = 400.0
freqRatio = (cutOffFrequency/sampleRate)
N = int(math.sqrt(0.196196 + freqRatio**2)/freqRatio)
```

So, in the example, the window length will be **11**

## Second step : coding the filter

### Hand-made moving average

see specific discussion on how to create a moving average in python

Solution from Alleo is

```
def running_mean(x, windowSize):
cumsum = numpy.cumsum(numpy.insert(x, 0, 0))
return (cumsum[windowSize:] - cumsum[:-windowSize]) / windowSize
filtered = running_mean(signal, N)
```

### Using lfilter

Alternatively, as suggested by dpwilson, we can also use lfilter

```
win = numpy.ones(N)
win *= 1.0/N
filtered = scipy.signal.lfilter(win, [1], signal)
```

## Third step : Let's Put It All Together

Example code is here

`scipy`

's lfilter? – dpwilson Jul 23 '14 at 20:35`sine_signal = np.sin(2*np.pi*freq*(np.arange(data_size)/frate))`

, then something like`wav_file.writeframes((sine_signal*amp/2).astype('h').tostring())`

. – dpwe Jul 24 '14 at 14:27