Digitizing an analog signal

I have a array of CSV values representing a digital output. It has been gathered using an analog oscilloscope so it is not a perfect digital signal. I'm trying to filter out the data to have a perfect digital signal for calculating the periods (which may vary). I would also like to define the maximum error i get from this filtration.

Something like this:

Idea

Apply a treshold od the data. Here is a pseudocode:

``````for data_point_raw in data_array:
if data_point_raw < 0.8: data_point_perfect = LOW
if data_point_raw > 2  : data_point_perfect = HIGH

else:
#area between thresholds
if previous_data_point_perfect == Low : data_point_perfect = LOW
if previous_data_point_perfect == HIGH: data_point_perfect = HIGH
``````

There are two problems bothering me.

1. This seems like a common problem in digital signal processing, however i haven't found a predefined standard function for it. Is this an ok way to perform the filtering?
2. How would I get the maximum error?
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Completely tangential, but an analog oscilloscope is much better on a bench than a digital scope. Digital scopes have a minimum granularity (both in input and display output) and have a tendency to gloss over outliers. –  L0j1k Feb 27 '13 at 13:14
Have you considered Matlab? in combination with Python, See This. and This –  Inbar Rose Feb 27 '13 at 13:15
@L0j1k Well, it's actually digital, we're just using the analog probes so we can do the conversion ourselves :) –  Alan Feb 27 '13 at 13:40
@InbarRose Sorry, matlab is out of the question. Don't know why you recommended the matplotlib link dough? The plot in the question has been generated by it, and edited a bit in Libre office Draw. –  Alan Feb 27 '13 at 13:42

Here's a bit of code that might help.

``````from __future__ import division

import numpy as np

def find_transition_times(t, y, threshold):
"""
Given the input signal `y` with samples at times `t`,
find the times where `y` increases through the value `threshold`.

`t` and `y` must be 1-D numpy arrays.

Linear interpolation is used to estimate the time `t` between
samples at which the transitions occur.
"""
# Find where y crosses the threshold (increasing).
lower = y < threshold
higher = y >= threshold
transition_indices = np.where(lower[:-1] & higher[1:])[0]

# Linearly interpolate the time values where the transition occurs.
t0 = t[transition_indices]
t1 = t[transition_indices + 1]
y0 = y[transition_indices]
y1 = y[transition_indices + 1]
slope = (y1 - y0) / (t1 - t0)
transition_times = t0 + (threshold - y0) / slope

return transition_times

def periods(t, y, threshold):
"""
Given the input signal `y` with samples at times `t`,
find the time periods between the times at which the
signal `y` increases through the value `threshold`.

`t` and `y` must be 1-D numpy arrays.
"""
transition_times = find_transition_times(t, y, threshold)
deltas = np.diff(transition_times)
return deltas

if __name__ == "__main__":
import matplotlib.pyplot as plt

# Time samples
t = np.linspace(0, 50, 501)
# Use a noisy time to generate a noisy y.
tn = t + 0.05 * np.random.rand(t.size)
y = 0.6 * ( 1 + np.sin(tn) + (1./3) * np.sin(3*tn) + (1./5) * np.sin(5*tn) +
(1./7) * np.sin(7*tn) + (1./9) * np.sin(9*tn))

threshold = 0.5
deltas = periods(t, y, threshold)
print "Measured periods at threshold %g:" % threshold
print deltas
print "Min:  %.5g" % deltas.min()
print "Max:  %.5g" % deltas.max()
print "Mean: %.5g" % deltas.mean()
print "Std dev: %.5g" % deltas.std()

trans_times = find_transition_times(t, y, threshold)

plt.plot(t, y)
plt.plot(trans_times, threshold * np.ones_like(trans_times), 'ro-')
plt.show()
``````

The output:

``````Measured periods at threshold 0.5:
[ 6.29283207  6.29118893  6.27425846  6.29580066  6.28310224  6.30335003]
Min:  6.2743
Max:  6.3034
Mean: 6.2901
Std dev: 0.0092793
``````

You could use `numpy.histogram` and/or `matplotlib.pyplot.hist` to further analyze the array returned by `periods(t, y, threshold)`.

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This is not an answer for your question, just and suggestion that may help. Im writing it here because i cant put image in comment.

I think you should normalize data somehow, before any processing.

After normalization to range of 0...1 you should apply your filter.

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Thanks for the tip. However, in this concrete example I'm converting the signal to boolean values so I don't see the benefit in normalization. –  Alan Feb 27 '13 at 16:01

If you're really only interested in the period, you could plot the Fourier Transform, you'll have a peak where the frequency of the signals occurs (and so you have the period). The wider the peak in the Fourier domain, the larger the error in your period measurement

``````import numpy as np

data = np.asarray(my_data)

np.fft.fft(data)
``````
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Cool idea, however, wi're looking to get a histogram of the periods so that we can tell in what percentage it suits our needs. It's for an experiment in the domain of implementing different software PWMs on raspberry py. –  Alan Feb 27 '13 at 13:44

Your filtering is fine, it's basically the same as a schmitt trigger, but the main problem you might have with it is speed. The benefit of using Numpy is that it can be as fast as C, whereas you have to iterate once over each element.

You can achieve something similar using the median filter from SciPy. The following should achieve a similar result (and not be dependent on any magnitudes):

``````filtered = scipy.signal.medfilt(raw)
filtered = numpy.where(filtered > numpy.mean(filtered), 1, 0)
``````

You can tune the strength of the median filtering with `medfilt(raw, n_samples)`, `n_samples` defaults to 3.

As for the error, that's going to be very subjective. One way would be to discretise the signal without filtering and then compare for differences. For example:

``````discrete = numpy.where(raw > numpy.mean(raw), 1, 0)
errors = np.count_nonzero(filtered != discrete)
error_rate = errors / len(discrete)
``````
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