34

I have been trying to get the result of a lognormal distribution using Scipy. I already have the Mu and Sigma, so I don't need to do any other prep work. If I need to be more specific (and I am trying to be with my limited knowledge of stats), I would say that I am looking for the cumulative function (cdf under Scipy). The problem is that I can't figure out how to do this with just the mean and standard deviation on a scale of 0-1 (ie the answer returned should be something from 0-1). I'm also not sure which method from dist, I should be using to get the answer. I've tried reading the documentation and looking through SO, but the relevant questions (like this and this) didn't seem to provide the answers I was looking for.

Here is a code sample of what I am working with. Thanks.

from scipy.stats import lognorm
stddev = 0.859455801705594
mean = 0.418749176686875
total = 37
dist = lognorm.cdf(total,mean,stddev)

UPDATE:

So after a bit of work and a little research, I got a little further. But I still am getting the wrong answer. The new code is below. According to R and Excel, the result should be .7434, but that's clearly not what is happening. Is there a logic flaw I am missing?

dist = lognorm([1.744],loc=2.0785)
dist.cdf(25)  # yields=0.96374596, expected=0.7434

UPDATE 2: Working lognorm implementation which yields the correct 0.7434 result.

def lognorm(self,x,mu=0,sigma=1):
   a = (math.log(x) - mu)/math.sqrt(2*sigma**2)
   p = 0.5 + 0.5*math.erf(a)
   return p
lognorm(25,1.744,2.0785)
> 0.7434
7
  • 2
    could you explain what do you understand for "the result of a distribution" ?
    – joaquin
    Jan 15, 2012 at 15:53
  • @joaquin I added a code sample that shows what I have and what I expect it to yield.
    – Eric Lubow
    Jan 16, 2012 at 0:59
  • @EricLubow: I think you might be misunderstanding what mean and stddev mean in this case. For the lognormal distribution they are the mean and stddev of the logarithm of the variable. If a variable is lognormally distributed, it implies that the logarithm of the variable is normally distributed.
    – talonmies
    Jan 17, 2012 at 17:29
  • @talonmies I understand that using the mean and stddev means using the mean and stddev of a log of the variable. I wrote the lognorm function in Python by hand (seen above) and was able to get the correct answer. This is what leads me to believe that there may be a difference in implementation in SciPy since I get the right answer in R and Excel. If I am wrong with my implementation, I'd definitely like to know.
    – Eric Lubow
    Jan 17, 2012 at 19:52
  • @EricLubow: you pretty much reimplemented what scipy uses internally Lucas's answer seems right. See my answer for a usage example.
    – serv-inc
    Apr 19, 2016 at 9:43

7 Answers 7

48

I know this is a bit late (almost one year!) but I've been doing some research on the lognorm function in scipy.stats. A lot of folks seem confused about the input parameters, so I hope to help these people out. The example above is almost correct, but I found it strange to set the mean to the location ("loc") parameter - this signals that the cdf or pdf doesn't 'take off' until the value is greater than the mean. Also, the mean and standard deviation arguments should be in the form exp(Ln(mean)) and Ln(StdDev), respectively.

Simply put, the arguments are (x, shape, loc, scale), with the parameter definitions below:

loc - No equivalent, this gets subtracted from your data so that 0 becomes the infimum of the range of the data.

scale - exp μ, where μ is the mean of the log of the variate. (When fitting, typically you'd use the sample mean of the log of the data.)

shape - the standard deviation of the log of the variate.

I went through the same frustration as most people with this function, so I'm sharing my solution. Just be careful because the explanations aren't very clear without a compendium of resources.

For more information, I found these sources helpful:

And here is an example, taken from @serv-inc 's answer, posted on this page here:

import math
from scipy import stats

# standard deviation of normal distribution
sigma = 0.859455801705594
# mean of normal distribution
mu = 0.418749176686875
# hopefully, total is the value where you need the cdf
total = 37

frozen_lognorm = stats.lognorm(s=sigma, scale=math.exp(mu))
frozen_lognorm.cdf(total) # use whatever function and value you need here
4
  • 3
    If I get that correct: in mathematical notation if X is N(mu,sigma) then Y=exp(X) is LogN(mu, sigma). To get X in scipy I would use norm(mu,sigma) but to get Y I would use lognorm(sigma, 0, exp(mu)). This is awkward... Oct 8, 2014 at 22:11
  • 5
    BTW: I found your post helpful, but not the scipy help. For each and every distribution you really have to try out what the meaning of the parameters may be (e.g. for the uniform distribution U(a,b), where [a,b] is the interval you need uniform(loc=a, scale=b-a), here loc is not the mean, neither scale the stddev...) Oct 8, 2014 at 22:14
  • 4
    @ElmarZander: you could use lognorm(s=sigma, scale=math.exp(mu). See stackoverflow.com/a/36714419/1587329
    – serv-inc
    Apr 19, 2016 at 9:45
  • 1
    @Lucas Better late than never ;) Thank you so much. Very useful summary of what is what. Jun 24, 2016 at 8:58
24

It sounds like you want to instantiate a "frozen" distribution from known parameters. In your example, you could do something like:

from scipy.stats import lognorm
stddev = 0.859455801705594
mean = 0.418749176686875
dist=lognorm([stddev],loc=mean)

which will give you a lognorm distribution object with the mean and standard deviation you specify. You can then get the pdf or cdf like this:

import numpy as np
import pylab as pl
x=np.linspace(0,6,200)
pl.plot(x,dist.pdf(x))
pl.plot(x,dist.cdf(x))

lognorm cdf and pdf

Is this what you had in mind?

7
  • 1
    typo: instead of "np.inspace" must be "np.linspace"
    – Max Li
    Jan 15, 2012 at 16:34
  • should it not be "dist=lognorm([stddev**2],loc=mean)", i.e. variance and not the standard deviation as the parameter? I didn't find the parameter specification in the scipy docs, are you aware of it?
    – Max Li
    Jan 15, 2012 at 16:45
  • I originally thought that myself (see the first version of the answer I posted) - but from calculations, the argument appears to be the "shape parameter", rather than the variance, so the standard deviation is the correct argument in this case.
    – talonmies
    Jan 15, 2012 at 16:48
  • variance could be also called "shape". in probability theory it's even rather kurtosis (4-th moment) that is called shape, however, they indeed use standard deviation (I've made some checks). here's my +1
    – Max Li
    Jan 15, 2012 at 17:02
  • 2
    So as per Lucas' answer below, this is wrong right? The mean shouldn't be at the far left of the distribution, it should be to the right of the peak, right?
    – Alex S
    Dec 22, 2014 at 17:34
14
from math import exp
from scipy import stats

def lognorm_cdf(x, mu, sigma):
    shape  = sigma
    loc    = 0
    scale  = exp(mu)
    return stats.lognorm.cdf(x, shape, loc, scale)

x      = 25
mu     = 2.0785
sigma  = 1.744
p      = lognorm_cdf(x, mu, sigma)  #yields the expected 0.74341

Similar to Excel and R, The lognorm_cdf function above parameterizes the CDF for the log-normal distribution using mu and sigma.

Although SciPy uses shape, loc and scale parameters to characterize its probability distributions, for the log-normal distribution I find it slightly easier to think of these parameters at the variable level rather than at the distribution level. Here's what I mean...

A log-normal variable X is related to a normal variable Z as follows:

X = exp(mu + sigma * Z)              #Equation 1

which is the same as:

X = exp(mu) * exp(Z)**sigma          #Equation 2

This can be sneakily re-written as follows:

X = exp(mu) * exp(Z-Z0)**sigma       #Equation 3

where Z0 = 0. This equation is of the form:

f(x) = a * ( (x-x0) ** b )           #Equation 4

If you can visualize equations in your head it should be clear that the scale, shape and location parameters in Equation 4 are: a, b and x0, respectively. This means that in Equation 3 the scale, shape and location parameters are: exp(mu), sigma and zero, respectfully.

If you can't visualize that very clearly, let's rewrite Equation 2 as a function:

f(Z) = exp(mu) * exp(Z)**sigma      #(same as Equation 2)

and then look at the effects of mu and sigma on f(Z). The figure below holds sigma constant and varies mu. You should see that mu vertically scales f(Z). However, it does so in a nonlinear manner; the effect of changing mu from 0 to 1 is smaller than the effect of changing mu from 1 to 2. From Equation 2 we see that exp(mu) is actually the linear scaling factor. Hence SciPy's "scale" is exp(mu).

effects_of_mu

The next figure holds mu constant and varies sigma. You should see that the shape of f(Z) changes. That is, f(Z) has a constant value when Z=0 and sigma affects how quickly f(Z) curves away from the horizontal axis. Hence SciPy's "shape" is sigma.

effects_of_sigma

2
  • Care to explain why this is the answer to the question?
    – MeanGreen
    Feb 27, 2017 at 9:31
  • I've found that this maps 1:1 with the Excel function LOGNORM.DIST(x, Mu, Sigma, TRUE)
    – asdag8
    Feb 27, 2017 at 15:27
4

@lucas' answer has the usage down pat. As a code example, you could use

import math
from scipy import stats

# standard deviation of normal distribution
sigma = 0.859455801705594
# mean of normal distribution
mu = 0.418749176686875
# hopefully, total is the value where you need the cdf
total = 37

frozen_lognorm = stats.lognorm(s=sigma, scale=math.exp(mu))
frozen_lognorm.cdf(total) # use whatever function and value you need here
3

Even more late, but in case it's helpful to anyone else: I found that the Excel's

LOGNORM.DIST(x,Ln(mean),standard_dev,TRUE)

provides the same results as python's

from scipy.stats import lognorm
lognorm.cdf(x,sigma,0,mean)

Likewise, Excel's

LOGNORM.DIST(x,Ln(mean),standard_dev,FALSE)

seems equivalent to Python's

from scipy.stats import lognorm
lognorm.pdf(x,sigma,0,mean).
2
  • For the first case, they didn't return the same result for me where x=2039.9337873, mean=7.6901, std_dev=0.6772 Jan 21, 2016 at 18:48
  • Ah, I forgot to add the Ln(mean) in my excel formula. Corrected in answer.
    – Docuemada
    Feb 2, 2016 at 22:51
3

Known mean and stddev of the lognormal distribution

In case someone is looking for it, here is a solution for getting the scipy.stats.lognorm distribution if the mean mu and standard deviation sigma of the lognormal distribution are known. In this case we have to calculate the stats.lognorm parameters from the known mu and sigma like so:

import numpy as np
from scipy import stats

mu = 10
sigma = 3

a = 1 + (sigma / mu) ** 2
s = np.sqrt(np.log(a))
scale = mu / np.sqrt(a)

This was obtained by looking into the implementation of the variance and mean calculations in the stats.lognorm.stats method and essentially reversing it (solving for the input).

Then we can initialize the frozen distribution instance

distr = stats.lognorm(s, 0, scale)

# generate some randomvals
randomvals = distr.rvs(1_000_000)
# calculate mean and variance using the dedicated method
mu_stats, var_stats = distr.stats("mv")

Compare means and stddevs from input, randomvals and analytical solution from distr.stats:

print(f"""
                 Mean    Std
----------------------------
Input:         {mu:6.2f} {sigma:6.2f}
Randomvals:    {randomvals.mean():6.2f} {randomvals.std():6.2f}
lognorm.stats: {mu_stats:6.2f} {np.sqrt(var_stats):6.2f}
""")

                 Mean    Std
----------------------------
Input:          10.00   3.00
Randomvals:     10.00   3.00
lognorm.stats:  10.00   3.00

Plot PDF from stats.lognorm and histogram of the random values:

import holoviews as hv
hv.extension('bokeh')

x = np.linspace(0, 30, 301)
counts, _ = np.histogram(randomvals, bins=x)
counts = counts / counts.sum() / (x[1] - x[0])

(hv.Histogram((counts, x)) 
* hv.Curve((x, distr.pdf(x))).opts(color="r").opts(width=900))

enter image description here

1

If you read this and just want a function with the behaviour similar to lnorm in R. Well, then relieve yourself from violent anger and use numpy's numpy.random.lognormal.

0

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