# Creating lowpass filter in SciPy - understanding methods and units

I am trying to filter a noisy heart rate signal with python. Because heart rates should never be above about 220 beats per minute, I want to filter out all noise above 220 bpm. I converted 220/minute into 3.66666666 Hertz and then converted that Hertz to rad/s to get 23.0383461 rad/sec.

The sampling frequency of the chip that takes data is 30Hz so I converted that to rad/s to get 188.495559 rad/s.

After looking up some stuff online I found some functions for a bandpass filter that I wanted to make into a lowpass. Here is the link the bandpass code, so I converted it to be this:

``````from scipy.signal import butter, lfilter
from scipy.signal import freqs

def butter_lowpass(cutOff, fs, order=5):
nyq = 0.5 * fs
normalCutoff = cutOff / nyq
b, a = butter(order, normalCutoff, btype='low', analog = True)
return b, a

def butter_lowpass_filter(data, cutOff, fs, order=4):
b, a = butter_lowpass(cutOff, fs, order=order)
y = lfilter(b, a, data)
return y

cutOff = 23.1 #cutoff frequency in rad/s
fs = 188.495559 #sampling frequency in rad/s
order = 20 #order of filter

#print sticker_data.ps1_dxdt2

y = butter_lowpass_filter(data, cutOff, fs, order)
plt.plot(y)
``````

I am very confused by this though because I am pretty sure the butter function takes in the cutoff and sampling frequency in rad/s but I seem to be getting a weird output. Is it actually in Hz?

Secondly, what is the purpose of these two lines:

``````    nyq = 0.5 * fs
normalCutoff = cutOff / nyq
``````

I know it's something about normalization but I thought the nyquist was 2 times the sampling requency, not one half. And why are you using the nyquist as a normalizer?

Can someone explain more about how to create filters with these functions?

I plotted the filter using:

``````w, h = signal.freqs(b, a)
plt.plot(w, 20 * np.log10(abs(h)))
plt.xscale('log')
plt.title('Butterworth filter frequency response')
plt.ylabel('Amplitude [dB]')
plt.margins(0, 0.1)
plt.grid(which='both', axis='both')
plt.axvline(100, color='green') # cutoff frequency
plt.show()
``````

and got this which clearly does not cut-off at 23 rad/s:

• The Nyquist frequency is half the sampling rate.
• You are working with regularly sampled data, so you want a digital filter, not an analog filter. This means you should not use `analog=True` in the call to `butter`, and you should use `scipy.signal.freqz` (not `freqs`) to generate the frequency response.
• One goal of those short utility functions is to allow you to leave all your frequencies expressed in Hz. You shouldn't have to convert to rad/sec. As long as you express your frequencies with consistent units, the `fs` parameter of the SciPy functions will take care of the scaling for you.

Here's my modified version of your script, followed by the plot that it generates.

``````import numpy as np
from scipy.signal import butter, lfilter, freqz
import matplotlib.pyplot as plt

def butter_lowpass(cutoff, fs, order=5):
return butter(order, cutoff, fs=fs, btype='low', analog=False)

def butter_lowpass_filter(data, cutoff, fs, order=5):
b, a = butter_lowpass(cutoff, fs, order=order)
y = lfilter(b, a, data)
return y

# Filter requirements.
order = 6
fs = 30.0       # sample rate, Hz
cutoff = 3.667  # desired cutoff frequency of the filter, Hz

# Get the filter coefficients so we can check its frequency response.
b, a = butter_lowpass(cutoff, fs, order)

# Plot the frequency response.
w, h = freqz(b, a, fs=fs, worN=8000)
plt.subplot(2, 1, 1)
plt.plot(w, np.abs(h), 'b')
plt.plot(cutoff, 0.5*np.sqrt(2), 'ko')
plt.axvline(cutoff, color='k')
plt.xlim(0, 0.5*fs)
plt.title("Lowpass Filter Frequency Response")
plt.xlabel('Frequency [Hz]')
plt.grid()

# Demonstrate the use of the filter.
# First make some data to be filtered.
T = 5.0         # seconds
n = int(T * fs) # total number of samples
t = np.linspace(0, T, n, endpoint=False)
# "Noisy" data.  We want to recover the 1.2 Hz signal from this.
data = np.sin(1.2*2*np.pi*t) + 1.5*np.cos(9*2*np.pi*t) + 0.5*np.sin(12.0*2*np.pi*t)

# Filter the data, and plot both the original and filtered signals.
y = butter_lowpass_filter(data, cutoff, fs, order)

plt.subplot(2, 1, 2)
plt.plot(t, data, 'b-', label='data')
plt.plot(t, y, 'g-', linewidth=2, label='filtered data')
plt.xlabel('Time [sec]')
plt.grid()
plt.legend()

• @samjewell It's a random number that I seem to always use with `freqz`. I like a smooth plot, with enough excess resolution that I can zoom in a bit without having to regenerate the plot, and 8000 is big enough to accomplish that in most cases. Commented Dec 1, 2015 at 22:54