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Lets assume we have a dataset which might be given approximately by

import numpy as np
x = np.linspace(0,2*np.pi,100)
y = np.sin(x) + np.random.random(100) * 0.2

Therefore we have a variation of 20% of the dataset. My first idea was to use the UnivariateSpline function of scipy, but the problem is that this does not consider the small noise in a good way. If you consider the frequencies, the background is much smaller than the signal, so a spline only of the cutoff might be an idea, but that would involve a back and forth fourier transformation, which might result in bad behaviour. Another way would be a moving average, but this would also need the right choice of the delay.

Any hints/ books or links how to tackle this problem?


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Will your signal always be a sine wave, or were you using that only for an example? – Mark Ransom Dec 16 '13 at 19:19
no, I will have different signals, even in this easy example it's obvious that my methods are not sufficient – varantir Dec 16 '13 at 19:23

5 Answers 5

If you are interested in a "smooth" version of a signal that is periodic (like your example), then a FFT is the right way to go. Take the fourier transform and subtract out the low-contributing frequencies:

import numpy as np
import scipy.fftpack

N = 100
x = np.linspace(0,2*np.pi,N)
y = np.sin(x) + np.random.random(N) * 0.2

w = scipy.fftpack.rfft(y)
f = scipy.fftpack.rfftfreq(N, x[1]-x[0])
spectrum = w**2

cutoff_idx = spectrum < (spectrum.max()/5)
w2 = w.copy()
w2[cutoff_idx] = 0

y2 = scipy.fftpack.irfft(w2)

enter image description here

Even if your signal is not completely periodic, this will do a great job of subtracting out white noise. There a many types of filters to use (high-pass, low-pass, etc...), the appropriate one is dependent on what you are looking for.

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I prefer a Savitzky-Golay filter. It uses least squares to regress a small window of your data onto a polynomial, then uses the polynomial to estimate the point in the center of the window. Finally the window is shifted forward by one data point and the process repeats. This continues until every point has been optimally adjusted relative to its neighbors. It works great even with noisy samples from non-periodic and non-linear sources.

Here is a thorough cookbook example. See my code below to get an idea of how easy it is to use. Note: I left out the code for defining the savitzky_golay() function because you can literally copy/paste it from the cookbook example I linked above.

import numpy as np
import matplotlib.pyplot as plt

x = np.linspace(0,2*np.pi,100)
y = np.sin(x) + np.random.random(100) * 0.2
yhat = savitzky_golay(y, 51, 3) # window size 51, polynomial order 3

plt.plot(x,yhat, color='red')

optimally smoothing a noisy sinusoid

UPDATE: It has come to my attention that the cookbook example I linked to has been taken down. Fortunately it looks like the Savitzky-Golay filter has been incorporated into the SciPy library, as pointed out by dodohjk.

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I got the error Traceback (most recent call last): File "", line 79, in <module> ysm2 = savitzky_golay(y_data,51,3) File "", line 42, in savitzky_golay firstvals = y[0] - np.abs( y[1:half_window+1][::-1] - y[0] ) – March Ho Jan 26 at 15:43
Please could you update your link to your cookbook example – RexFuzzle Sep 24 at 12:29

Fitting a moving average to your data would smooth out the noise, see this this answer for how to do that.

If you'd like to use LOWESS to fit your data (it's similar to a moving average but more sophisticated), you can do that using the statsmodels library:

import numpy as np
import pylab as plt
import statsmodels.api as sm

x = np.linspace(0,2*np.pi,100)
y = np.sin(x) + np.random.random(100) * 0.2
lowess = sm.nonparametric.lowess(y, x, frac=0.1)

plt.plot(x, y, '+')
plt.plot(lowess[:, 0], lowess[:, 1])

Finally, if you know the functional form of your signal, you could fit a curve to your data, which would probably be the best thing to do.

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A quick and dirty way to smooth data I use, based on a moving average box (by convolution):

x = np.linspace(0,2*np.pi,100)
y = np.sin(x) + np.random.random(100) * 0.8

def smooth(y, box_pts):
    box = np.ones(box_pts)/box_pts
    y_smooth = np.convolve(y, box, mode='same')
    return y_smooth

plot(x, y,'o')
plot(x, smooth(y,3), 'r-', lw=2)
plot(x, smooth(y,9), 'g-', lw=2)
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This has a few nice advantages: (1) works for any function, not just periodic, and (2) no dependencies or large functions to copy-paste. You can do it right away with pure Numpy. Also, it's not too dirty--- it's a simplest case of some of the other methods described above (like LOWESS but the kernel is a sharp interval and like Savitzky-Golay but the polynomial degree is zero). – Jim Pivarski Feb 16 at 20:14

Another option is to use KernelReg in statsmodel:

from statsmodels.nonparametric.kernel_regression import KernelReg
import numpy as np
import matplotlib.pyplot as plt
x = np.linspace(0,2*np.pi,100)
y = np.sin(x) + np.random.random(100) * 0.2
kr = KernelReg(y,x,'o')
plt.plot(x, y, '+')
y_pred, y_std =
plt.plot(x, y_pred)
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