# Fitting a Weibull distribution using Scipy

I am trying to recreate maximum likelihood distribution fitting, I can already do this in Matlab and R, but now I want to use scipy. In particular, I would like to estimate the Weibull distribution parameters for my data set.

I have tried this:

``````import scipy.stats as s
import numpy as np
import matplotlib.pyplot as plt

def weib(x,n,a):
return (a / n) * (x / n)**(a - 1) * np.exp(-(x / n)**a)

(loc, scale) = s.exponweib.fit_loc_scale(data, 1, 1)
print loc, scale

x = np.linspace(data.min(), data.max(), 1000)
plt.plot(x, weib(x, loc, scale))
plt.hist(data, data.max(), normed=True)
plt.show()
``````

And get this:

``````(2.5827280639441961, 3.4955032285727947)
``````

And a distribution that looks like this:

I have been using the `exponweib` after reading this http://www.johndcook.com/distributions_scipy.html. I have also tried the other Weibull functions in scipy (just in case!).

In Matlab (using the Distribution Fitting Tool - see screenshot) and in R (using both the MASS library function `fitdistr` and the GAMLSS package) I get a (loc) and b (scale) parameters more like 1.58463497 5.93030013. I believe all three methods use the maximum likelihood method for distribution fitting.

I have posted my data here if you would like to have a go! And for completeness I am using Python 2.7.5, Scipy 0.12.0, R 2.15.2 and Matlab 2012b.

Why am I getting a different result!?

-
For maximum likelihood fitting, use the `fit` method, and use the keyword arguments `f0` and `floc` to fix the first shape parameter and the location. See @user333700's answer. –  Warren Weckesser Jul 6 '13 at 2:16
I'm not able to get the flat part at the beginning of the pdf plot with weibull_min or exponweib, (nor frechet or similar). Maybe there is an additional difference in the parameterization. –  user333700 Jul 6 '13 at 2:19
@user333700: You found the shape parameter to be 1.855. The slope of the PDF at 0 is 0 only when the shape parameter is greater than 2. –  Warren Weckesser Jul 6 '13 at 2:32
@user333700: Also, when I run `fitdistr(x, "weibull")` in R, I get `shape=1.85529987` and `scale=6.88224649`, which agrees pretty well with the `fit` method of `exponweib`. –  Warren Weckesser Jul 6 '13 at 2:37

My guess is that you want to estimate the shape parameter and the scale of the Weibull distribution while keeping the location fixed. Fixing `loc` assumes that the values of your data and of the distribution are positive with lower bound at zero.

`floc=0` keeps the location fixed at zero, `f0=1` keeps the first shape parameter of the exponential weibull fixed at one.

``````>>> stats.exponweib.fit(data, floc=0, f0=1)
[1, 1.8553346917584836, 0, 6.8820748596850905]
>>> stats.weibull_min.fit(data, floc=0)
[1.8553346917584836, 0, 6.8820748596850549]
``````

The fit compared to the histogram looks ok, but not very good. The parameter estimates are a bit higher than the ones you mention are from R and matlab.

Update

The closest I can get to the plot that is now available is with unrestricted fit, but using starting values. The plot is still less peaked. Note values in fit that don't have an f in front are used as starting values.

``````>>> from scipy import stats
>>> import matplotlib.pyplot as plt
>>> plt.plot(x, stats.exponweib.pdf(x, *stats.exponweib.fit(data, 1, 1, scale=02, loc=0)))
>>> _ = plt.hist(data, bins=np.linspace(0, 16, 33), normed=True, alpha=0.5);
>>> plt.show()
``````

-
Thank you user333700 and @Warren for your help with solving this! –  kungphil Jul 7 '13 at 10:59

It is easy to verify which result is the true MLE, just need a simple function to calculate log likelihood:

``````>>> def wb2LL(p, x): #log-likelihood
return sum(log(stats.weibull_min.pdf(x, p[1], 0., p[0])))
-8290.1227946678173
-8410.3327470347667
``````

The result from `fit` method of `exponweib` and R `fitdistr` (@Warren) is better and has higher log likelihood. It is more likely to be the true MLE. It is not surprising that the result from GAMLSS is different. It is a complete different statistic model: Generalized Additive Model.

Still not convinced? We can draw a 2D confidence limit plot around MLE, see Meeker and Escobar's book for detail).

Again this verifies that `array([6.8820748596850905, 1.8553346917584836])` is the right answer as loglikelihood is lower that any other point in the parameter space. Note:

``````>>> log(array([6.8820748596850905, 1.8553346917584836]))
array([ 1.92892018,  0.61806511])
``````

BTW1, MLE fit may not appears to fit the distribution histogram tightly. An easy way to think about MLE is that MLE is the parameter estimate most probable given the observed data. It doesn't need to visually fit the histogram well, that will be something minimizing mean square error.

BTW2, your data appears to be leptokurtic and left-skewed, which means Weibull distribution may not fit your data well. Try, e.g. Gompertz-Logistic, which improves log-likelihood by another about 100. Cheers!

-

I was curious about your question and, despite this is not an answer, it compares the `Matlab` result with your result and with the result using `leastsq`, which showed the best correlation with the given data:

The code is as follows:

``````import scipy.stats as s
import numpy as np
import matplotlib.pyplot as plt
import numpy.random as mtrand
from scipy.optimize import leastsq

## my distribution (Inverse Normal with shape parameter mu=1.0)
def weib(x,n,a):
return (a / n) * (x / n)**(a-1) * np.exp(-(x/n)**a)

def residuals(p,x,y):
integral = quad( weib, 0, 16, args=(p[0],p[1]) )[0]
penalization = abs(1.-integral)*100000
return y - weib(x, p[0],p[1]) + penalization

#

x = np.linspace(data.min(), data.max(), 100)
n, bins, patches = plt.hist(data,bins=x, normed=True)
binsm = (bins[1:]+bins[:-1])/2

popt, pcov = leastsq(func=residuals, x0=(1.,1.), args=(binsm,n))

loc, scale = 1.58463497, 5.93030013
plt.plot(binsm,n)
plt.plot(x, weib(x, loc, scale),
label='weib matlab, loc=%1.3f, scale=%1.3f' % (loc, scale), lw=4.)
loc, scale = s.exponweib.fit_loc_scale(data, 1, 1)
plt.plot(x, weib(x, loc, scale),
label='weib stack, loc=%1.3f, scale=%1.3f' % (loc, scale), lw=4.)
plt.plot(x, weib(x,*popt),
label='weib leastsq, loc=%1.3f, scale=%1.3f' % tuple(popt), lw=4.)

plt.legend(loc='upper right')
plt.show()
``````
-
``````plt.plot(x, weib(x, scale, loc))