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Is it possible to generate distributions in R for which the Mean, SD, skew and kurtosis are known? So far it appears the best route would be to create random numbers and transform them accordingly. If there is a package tailored to generating specific distributions which could be adapted, I have not yet found it. Thanks

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As noted those don't uniquely describe a distribution. Even if you define all of the moments you're not guaranteed to uniquely define a distribution. I think you need to explain what it is you're exactly trying to do. Why are you trying to do this? Can you place further restrictions that would make it possible to define a distribution? –  Dason Jan 26 '11 at 17:41
Ah yes, we want unimodal, continuous distributions in a single dimension. The resultant distributions will eventually be transformed numerically as a way to test a variation of niche theory through simulation. –  Aaron B Jan 27 '11 at 15:55

5 Answers 5

up vote 17 down vote accepted

There is a Johnson distribution in the SuppDists package. Johnson will give you a distribution that matches either moments or quantiles. Others comments are correct that 4 moments does not a distribution make. But Johnson will certainly try.

Here's an example of fitting a Johnson to some sample data:


## make a weird dist with Kurtosis and Skew
a <- rnorm( 5000, 0, 2 )
b <- rnorm( 1000, -2, 4 )
c <- rnorm( 3000,  4, 4 )
babyGotKurtosis <- c( a, b, c )
hist( babyGotKurtosis , freq=FALSE)

## Fit a Johnson distribution to the data
## TODO: Insert Johnson joke here
parms<-JohnsonFit(babyGotKurtosis, moment="find")

## Print out the parameters 

## add the Johnson function to the histogram
plot(function(x)dJohnson(x,parms), -20, 20, add=TRUE, col="red")

The final plot looks like this:

enter image description here

You can see a bit of the issue that others point out about how 4 moments do not fully capture a distribution.

Good luck!

EDIT As Hadley pointed out in the comments, the Johnson fit looks off. I did a quick test and fit the Johnson distribution using moment="quant" which fits the Johnson distribution using 5 quantiles instead of the 4 moments. The results look much better:

parms<-JohnsonFit(babyGotKurtosis, moment="quant")
plot(function(x)dJohnson(x,parms), -20, 20, add=TRUE, col="red")

Which produces the following:

enter image description here

Anyone have any ideas why Johnson seems biased when fit using moments?

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Something looks wrong with that curve - a simple position shift would make the fit substantially better –  hadley Jan 28 '11 at 15:40
I agree it looks off. When I get a little time I may dig into it a tad. –  JD Long Jan 28 '11 at 15:46

This is an interesting question, which doesn't really have a good solution. I presume that even though you don't know the other moments, you have an idea of what the distribution should look like. For example, it's unimodal.

There a few different ways of tackling this problem:

  1. Assume an underlying distribution and match moments. There are many standard R packages for doing this. One downside is that the multivariate generalisation may be unclear.

  2. Saddlepoint approximations. In this paper:

    Gillespie, C.S. and Renshaw, E. An improved saddlepoint approximation. Mathematical Biosciences, 2007.

    We look at recovering a pdf/pmf when given only the first few moments. We found that this approach works when the skewness isn't too large.

  3. Laguerre expansions:

    Mustapha, H. and Dimitrakopoulosa, R. Generalized Laguerre expansions of multivariate probability densities with moments. Computers & Mathematics with Applications, 2010.

    The results in this paper seem more promising, but I haven't coded them up.

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Those parameters don't actually fully define a distribution. For that you need a density or equivalently a distribution function.

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As @David and @Carl wrote above, there are several packages dedicated to generate different distributions, see e.g. the Probability distributions Task View on CRAN.

If you are interested in the theory (how to draw a sample of numbers fitting to a specific distribution with the given parameters) then just look for the appropriate formulas, e.g. see the gamma distribution on Wiki, and make up a simple quality system with the provided parameters to compute scale and shape.

See a concrete example here, where I computed the alpha and beta parameters of a required beta distribution based on mean and standard deviation.

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Could you please specify why I got the downvote? –  daroczig Jan 28 '11 at 16:05

I agree you need density estimation to replicate any distribution. However, if you have hundreds of variables, as is typical in a Monte Carlo simulation, you would need to have a compromise.

One suggested approach is as follows:

  1. Use the Fleishman transform to get the coefficient for the given skew and kurtosis. Fleishman takes the skew and kurtosis and gives you the coefficients
  2. Generate N normal variables (mean = 0, std = 1)
  3. Transform the data in (2) with the Fleishman coefficients to transform the normal data to the given skew and kurtosis
  4. In this step, use data from from step (3) and transform it to the desired mean and standard deviation (std) using new_data = desired mean + (data from step 3)* desired std

The resulting data from Step 4 will have the desired mean, std, skewness and kurtosis.


  1. Fleishman will not work for all combinations of skewness and kurtois
  2. Above steps assume non-correlated variables. If you want to generate correlated data, you will need a step before the Fleishman transform
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There are R implementation of this? –  Artem Klevtsov Nov 26 '13 at 8:18

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