# Matplotlib histogram with log Laplacian PDF

(be sure to check out the EDIT at the end of the post before reading too deeply into the source)

I'm plotting a histogram of a population that seems to be of log Laplacian distribution:

I'm trying to draw a line of best fit for it to verify my hypothesis, but I'm having problems getting meaningful results.

I'm using the Laplacian PDF definition from Wikipedia and taking 10 to the power of the PDF (to "reverse" the effects of the log histogram).

What am I doing wrong?

Here is my code. I pipe things through standard input (`cat pop.txt | python hist.py`) -- here's a sample population.

``````from pylab import *
import numpy
def laplace(x, mu, b):
return 10**(1.0/(2*b) * numpy.exp(-abs(x - mu)/b))
def main():
import sys
nbins = max(num) - min(num)
n, bins, patches = hist(num, nbins, range=(min(num), max(num)), log=True, align='left')
loc, scale = 0., 1.
x = numpy.arange(bins[0], bins[-1], 1.)
pdf = laplace(x, 0., 1.)
plot(x, pdf)
width = max(-min(num), max(num))
xlim((-width, width))
ylim((1.0, 10**7))
show()
if __name__ == '__main__':
main()
``````

EDIT

OK, here is the attempt to match it to a regular Laplacian distribution (as opposed to a log Laplacian). Differences from above attempt:

• histogram is normed
• histogram is linear (not log)
• `laplace` function defined exactly as specified in the Wikipedia article

Output:

As you can see, it isn't the best match, but the figures (the histogram and the Laplace PDF) are at least now in the same ballpark. I think the log Laplace will match a lot better. My approach (source above) didn't work. Can anybody suggest a way to do this what works?

Source:

``````from pylab import *
import numpy
def laplace(x, mu, b):
return 1.0/(2*b) * numpy.exp(-abs(x - mu)/b)
def main():
import sys
nbins = max(num) - min(num)
n, bins, patches = hist(num, nbins, range=(min(num), max(num)), log=False, align='left', normed=True)
loc, scale = 0., 0.54
x = numpy.arange(bins[0], bins[-1], 1.)
pdf = laplace(x, loc, scale)
plot(x, pdf)
width = max(-min(num), max(num))
xlim((-width, width))
show()
if __name__ == '__main__':
main()
``````
-

1. Your laplace() function does not seem to be a Laplace distribution. Besides, `numpy.log()` is a natural logarithm (base `e`), not decimal.

2. Your histogram does not seem to be normalized, while the distribution is.

EDIT:

1. Don't use blanket imports `from pyplot import *`, it'll bite you.

2. If you're checking consistency with Laplace distribution (or its log), use the fact that the latter is symmetric around `mu`: fix `mu` at a maximum of your histogram, and you have a single-parameter problem. And you can only use either half of the histogram as well.

3. Use `numpy`'s histogram function -- this way you can get the histogram itself, which you can then fit with a Laplace distribution (and/or its log). The chi-square will tell you how good (or bad) the consistency is. For fitting you can use, e.g. `scipy.optimize.leastsq` routine (http://www.scipy.org/Cookbook/FittingData)

-
@Zhenya, thanks for your comments. Why do you say that my `laplace()` function is not a Laplace distribution? If you have a look at the Wikipedia page, you will see that I've implemented the Laplace PDF exactly as defined (with the exception that afterwards I'm taking the exponential of base 10, as mentioned in my original post). It seems like you're right about the log base. I got confused by the fact that the ticks on the y-axis are powers of 10. It seems like the base is indeed `e`. Regarding your second point, I'll look into norming the histogram, thanks. –  misha May 20 '11 at 10:48
@misha: I just don't understand why do you take 10**laplace_distribution; maybe it's related to what your raw data actually are. –  Zhenya May 20 '11 at 11:01
@Zhenya: I do that because the log of my population's PDF looks like a Laplacian (not the usual PDF itself). See how the scale of the y axis is logarithmic? A normal Laplacian distribution would not work here. Also, that should really be `exp(laplace_distribution)` since the log is base `e`. –  misha May 20 '11 at 13:05
@Zhenya: I updated the post with an attempt to match to the regular Laplace distribution. Perhaps now it will be clearer what I am trying to do. –  misha May 20 '11 at 13:29
@misha: looks like you're using different datasets in two pictures ;-). I've updated the answer with a few (almost random) thoughts. –  Zhenya May 20 '11 at 15:17

I've found a work-around for the problem I was having. Instead of using `matplotlib.hist`, I use `numpy.histogram` in combination with `matplotlib.bar` to calculate the histogram and draw it in two separate steps.

I'm not sure if there's a way to do this using `matplotlib.hist` -- it would definitely be more convenient, though.

You can see that it's a much better match.

My problem now is I need to estimate the `scale` parameter of the PDF.

Source:

``````from pylab import *
import numpy

def laplace(x, mu, b):
"""http://en.wikipedia.org/wiki/Laplace_distribution"""
return 1.0/(2*b) * numpy.exp(-abs(x - mu)/b)

def main():
import sys
nbins = max(num) - min(num)
count, bins = numpy.histogram(num, nbins)
bins = bins[:-1]
assert len(bins) == nbins
#
# FIRST we take the log of the histogram, THEN we normalize it.
# Clean up after divide by zero
#
count = numpy.log(count)
for i in range(nbins):
if count[i] == -numpy.inf:
count[i] = 0
count = count/max(count)

loc = 0.
scale = 4.
x = numpy.arange(bins[0], bins[-1], 1.)
pdf = laplace(x, loc, scale)
pdf = pdf/max(pdf)

width=1.0
bar(bins-width/2, count, width=width)
plot(x, pdf, color='r')
xlim(min(num), max(num))
show()

if __name__ == '__main__':
main()
``````
-
you're almost there :-). See my edit for a suggestion on fitting. –  Zhenya May 20 '11 at 15:25