# Numpy Root-Mean-Squared (RMS) smoothing of a signal

I have a signal of electromyographical data that I am supposed (scientific papers' explicit recommendation) to smooth using RMS.

I have the following working code, producing the desired output, but it is way slower than I think it's possible.

``````#!/usr/bin/python
import numpy
def rms(interval, halfwindow):
""" performs the moving-window smoothing of a signal using RMS """
n = len(interval)
rms_signal = numpy.zeros(n)
for i in range(n):
small_index = max(0, i - halfwindow)  # intended to avoid boundary effect
big_index = min(n, i + halfwindow)    # intended to avoid boundary effect
window_samples = interval[small_index:big_index]

# here is the RMS of the window, being attributed to rms_signal 'i'th sample:
rms_signal[i] = sqrt(sum([s**2 for s in window_samples])/len(window_samples))

return rms_signal
``````

I have seen some `deque` and `itertools` suggestions regarding optimization of moving window loops, and also `convolve` from numpy, but I couldn't figure it out how to accomplish what I want using them.

Also, I do not care to avoid boundary problems anymore, because I end up having large arrays and relatively small sliding windows.

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Can you link to the paper? I've never heard of smoothing a signal by computing the RMS of the points over a moving window. In general, this will not look like a smoothed version of the original signal. – user545424 Nov 23 '11 at 20:19
Smoothing this way is suggested because it correlates with signal power (energy), and this could be used to infer muscle effort. Link: isek-online.org/standards_emg.html "Another acceptable method of providing amplitude information is the "Root Mean Square" or RMS. Just as the moving average, this quantity is defined for a specific time interval (moving window) T which must be indicated." It is the first choice for smoothing according to Noraxon booklet (closed source, owned by my company) with a time window between 50 and 100ms more or less. – heltonbiker Nov 23 '11 at 20:30
RMS of a moving window is the idea behind audio level meters, too. – endolith Nov 23 '11 at 21:15

It is possible to use convolution to perform the operation you are referring to. I did it a few times for processing EEG signals as well.

``````import numpy as np
def window_rms(a, window_size):
a2 = np.power(a,2)
window = np.ones(window_size)/float(window_size)
return np.sqrt(np.convolve(a2, window, 'valid'))
``````

Breaking it down, the `np.power(a, 2)` part makes a new array with the same dimension as `a`, but where each value is squared. `np.ones(window_size)/float(window_size)` produces an array or length `window_size` where each element is `1/window_size`. So the convolution effectively produces a new array where each element `i` is equal to

``````(a[i]^2 + a[i+1]^2 + … + a[i+window_size]^2)/window_size
``````

which is the RMS value of the array elements within the moving window. It should perform really well this way.

Note, though, that `np.power(a, 2)` produces a new array of same dimension. If `a` is really large, I mean sufficiently large that it cannot fit twice in memory, you might need a strategy where each element are modified in place. Also, the `'valid'` argument specifies to discard border effects, resulting in a smaller array produced by `np.convolve()`. You could keep it all by specifying `'same'` instead (see documentation).

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Great, great, great, very clever! EMG signals are way shorter than EMG, less than 50mb for 4 channel recording, so memory usage won't be prohibitive. And I plan to use `'same'`, for display in stack with raw/smoothed/filtered signal. – heltonbiker Nov 24 '11 at 21:15
Just for the record, RMS now is 500 times faster (0.002 vs 1.000 s for `window_size' of 16 samples as measured by `cProfile'), and does not get much slower for way larger (100+) windows. Did I say it's great? – heltonbiker Nov 24 '11 at 22:29
Glad to hear that! – matehat Nov 24 '11 at 22:51
You should never specify anything other than 'valid' using the code you have since the second argument to `np.convolve()` contains the inverse of the full window length. – user545424 Dec 2 '11 at 23:57
Just to extend this a bit, it is possible to have `window` be a kernel whose sum is `1.0`, like normalized gaussian kernel, if some more esoteric behaviour is needed. Actually, the three lines of code in the function perform what some DSP texts generically call "delinearization", "demodulation" and "relinearization", which can be done with different power (besides two), kernel (besides unitary square or gaussian), statistical operator (besides weighted average) and window size. – heltonbiker Apr 25 '13 at 18:43

Since this is not a linear transformation, I don't believe it is possible to use np.convolve().

Here's a function which should do what you want. Note that the first element of the returned array is the rms of the first full window; i.e. for the array `a` in the example, the return array is the rms of the subwindows `[1,2],[2,3],[3,4],[4,5]` and does not include the partial windows `[1]` and `[5]`.

``````>>> def window_rms(a, window_size=2):
>>>     return np.sqrt(sum([a[window_size-i-1:len(a)-i]**2 for i in range(window_size-1)])/window_size)
>>> a = np.array([1,2,3,4,5])
>>> window_rms(a)
array([ 1.41421356,  2.44948974,  3.46410162,  4.47213595])
``````
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It is possible to use convolution, see my answer. – matehat Nov 24 '11 at 17:27