# 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 about 220 beats per minute i want to filter out all noise above 220bpm. 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 unctions 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 its 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 one 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.xlabel('Frequency [radians / second]')
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 that 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 scaling in the utility functions takes care of the normalization 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):
nyq = 0.5 * fs
normal_cutoff = cutoff / nyq
b, a = butter(order, normal_cutoff, btype='low', analog=False)
return b, a

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, worN=8000)
plt.subplot(2, 1, 1)
plt.plot(0.5*fs*w/np.pi, 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()

plt.show()
`````` • Yes, I'm sure. Consider the wording of "you need to sample at twice the bandwidth"; that says the sample rate must be twice the bandwidth of the signal. – Warren Weckesser Aug 7 '14 at 21:42
• In other words: You are sampling at 30 Hz. This means the bandwidth of your signal should not be more than 15 Hz; 15 Hz is the Nyquist frequency. – Warren Weckesser Aug 7 '14 at 21:51
• Resurrecting this: I saw in another thread a suggestion to use filtfilt which performs backwards/forwards filtering instead of lfilter. What is your opinion on that? – Bar Nov 10 '14 at 11:57
• @Bar: These comments aren't the right place to address your question. You could create a new stackoverflow question, but the moderators might close it because it isn't a programming question. The best place for it is probably dsp.stackexchange.com – Warren Weckesser Nov 10 '14 at 14:40
• @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. – Warren Weckesser Dec 1 '15 at 22:54

## protected by Community♦Aug 7 '18 at 19:59

Thank you for your interest in this question. Because it has attracted low-quality or spam answers that had to be removed, posting an answer now requires 10 reputation on this site (the association bonus does not count).

Would you like to answer one of these unanswered questions instead?