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UPDATE:

To my surprise, while looking for this same topic almost two years later, I found a Scipy Recipe based in this question! So, for anyone interested, go straight to:

http://wiki.scipy.org/Cookbook/ButterworthBandpass


I'm having a hard time to achieve what seemed initially a simple task of implementing a Butterworth band-pass filter for 1-D numpy array (time-series).

The parameters I have to include are the sample_rate, cutoff frequencies IN HERTZ and possibly order (other parameters, like attenuation, natural frequency, etc. are more obscure to me, so any "default" value would do).

What I have now is this, which seems to work as a high-pass filter but I'm no way sure if I'm doing it right:

def butter_highpass(interval, sampling_rate, cutoff, order=5):
    nyq = sampling_rate * 0.5

    stopfreq = float(cutoff)
    cornerfreq = 0.4 * stopfreq  # (?)

    ws = cornerfreq/nyq
    wp = stopfreq/nyq

    # for bandpass:
    # wp = [0.2, 0.5], ws = [0.1, 0.6]

    N, wn = scipy.signal.buttord(wp, ws, 3, 16)   # (?)

    # for hardcoded order:
    # N = order

    b, a = scipy.signal.butter(N, wn, btype='high')   # should 'high' be here for bandpass?
    sf = scipy.signal.lfilter(b, a, interval)
    return sf

enter image description here

The docs and examples are confusing and obscure, but I'd like to implement the form presented in the commend marked as "for bandpass". The question marks in the comments show where I just copy-pasted some example without understanding what is happening.

I am no electrical engineering or scientist, just a medical equipment designer needing to perform some rather straightforward bandpass filtering on EMG signals.

Thanks for any help!

share|improve this question
    
I've tried something at dsp.stackexchange, but they focus too much (more than I can handle) in conceptual issues of engineering and not so much in using the scipy functions. –  heltonbiker Aug 23 '12 at 14:11

2 Answers 2

up vote 32 down vote accepted

You could skip the use of buttord, and instead just pick an order for the filter and see if it meets your filtering criterion. To generate the filter coefficients for a bandpass filter, give butter() the filter order, the cutoff frequencies Wn=[low, high] (expressed as the fraction of the Nyquist frequency, which is half the sampling frequency) and the band type btype="band".

Here's a script that defines a couple convenience functions for working with a Butterworth bandpass filter. When run as a script, it makes two plots. One shows the frequency response at several filter orders for the same sampling rate and cutoff frequencies. The other plot demonstrates the effect of the filter (with order=6) on a sample time series.

from scipy.signal import butter, lfilter


def butter_bandpass(lowcut, highcut, fs, order=5):
    nyq = 0.5 * fs
    low = lowcut / nyq
    high = highcut / nyq
    b, a = butter(order, [low, high], btype='band')
    return b, a


def butter_bandpass_filter(data, lowcut, highcut, fs, order=5):
    b, a = butter_bandpass(lowcut, highcut, fs, order=order)
    y = lfilter(b, a, data)
    return y


if __name__ == "__main__":
    import numpy as np
    import matplotlib.pyplot as plt
    from scipy.signal import freqz

    # Sample rate and desired cutoff frequencies (in Hz).
    fs = 5000.0
    lowcut = 500.0
    highcut = 1250.0

    # Plot the frequency response for a few different orders.
    plt.figure(1)
    plt.clf()
    for order in [3, 6, 9]:
        b, a = butter_bandpass(lowcut, highcut, fs, order=order)
        w, h = freqz(b, a, worN=2000)
        plt.plot((fs * 0.5 / np.pi) * w, abs(h), label="order = %d" % order)

    plt.plot([0, 0.5 * fs], [np.sqrt(0.5), np.sqrt(0.5)],
             '--', label='sqrt(0.5)')
    plt.xlabel('Frequency (Hz)')
    plt.ylabel('Gain')
    plt.grid(True)
    plt.legend(loc='best')

    # Filter a noisy signal.
    T = 0.05
    nsamples = T * fs
    t = np.linspace(0, T, nsamples, endpoint=False)
    a = 0.02
    f0 = 600.0
    x = 0.1 * np.sin(2 * np.pi * 1.2 * np.sqrt(t))
    x += 0.01 * np.cos(2 * np.pi * 312 * t + 0.1)
    x += a * np.cos(2 * np.pi * f0 * t + .11)
    x += 0.03 * np.cos(2 * np.pi * 2000 * t)
    plt.figure(2)
    plt.clf()
    plt.plot(t, x, label='Noisy signal')

    y = butter_bandpass_filter(x, lowcut, highcut, fs, order=6)
    plt.plot(t, y, label='Filtered signal (%g Hz)' % f0)
    plt.xlabel('time (seconds)')
    plt.hlines([-a, a], 0, T, linestyles='--')
    plt.grid(True)
    plt.axis('tight')
    plt.legend(loc='upper left')

    plt.show()

Here are the plots that are generated by this script:

Frequency response for several filter orders

enter image description here

share|improve this answer
1  
Do you know why the filtered output always starts at value zero? Is it possible to match it with the actual input value x[0]? I tried similar stuff with Cheby1 low pass filter, and I got the same problem. –  LWZ Apr 3 '13 at 0:10
2  
@LWZ: Use the function scipy.signal.lfilter_zi, and the zi argument to lfilter. For details, see the docstring for lfilter_zi. TL;DR? Just change y = lfilter(b, a, data) to zi = lfilter_zi(b, a); y, zo = lfilter(b, a, data, zi=zi*data[0]). (But this might not make a difference with a bandpass or high pass filter.) –  Warren Weckesser Apr 3 '13 at 3:32

For a bandpass filter, ws is a tuple containing the lower and upper corner frequencies. These represent the digital frequency where the filter response is 3 dB less than the passband.

wp is a tuple containing the stop band digital frequencies. They represent the location where the maximum attenuation begins.

gpass is the maximum attenutation in the passband in dB while gstop is the attentuation in the stopbands.

Say, for example, you wanted to design a filter for a sampling rate of 8000 samples/sec having corner frequencies of 300 and 3100 Hz. The Nyquist frequency is the sample rate divided by two, or in this example, 4000 Hz. The equivalent digital frequency is 1.0. The two corner frequencies are then 300/4000 and 3100/4000.

Now lets say you wanted the stopbands to be down 30 dB +/- 100 Hz from the corner frequencies. Thus, your stopbands would start at 200 and 3200 Hz resulting in the digital frequencies of 200/4000 and 3200/4000.

To create your filter, you'd call buttord as

fs = 8000.0
fso2 = fs/2
N,wn = scipy.signal.buttord(ws=[300/fso2,3100/fso2], wp=[200/fs02,3200/fs02],
   gpass=0.0, gstop=30.0)

The length of the resulting filter will be dependent upon the depth of the stop bands and the steepness of the response curve which is determined by the difference between the corner frequency and stopband frequency.

share|improve this answer
    
I tried to implement it, but something is still missing. One thing is that gpass=0.0 raises a division by zero error, so I changed it to 0.1 and the error stopped. Besides that, the docs for butter say: Passband and stopband edge frequencies, normalized from 0 to 1 (1 corresponds to pi radians / sample). I'm in doubt if your answer did the calculations right, so I'm still working on that and will give some feedback soon. –  heltonbiker Aug 23 '12 at 16:53
    
(also, although my ws and wp have two elements each, the filter only performs low or high pass (via btype argument), but not band-pass) –  heltonbiker Aug 23 '12 at 17:53
1  
According to the documentation at docs.scipy.org/doc/scipy/reference/generated/…, buttord designs low, high, and band pass filters. As far as gpass, I guess buttord doesn't allow 0 dB attenuation in the passband. Set it to some non-zero value then. –  sizzzzlerz Aug 23 '12 at 18:10

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