# Generating lognormally distributed random number from mean, coeff of variation

Most functions for generating lognormally distributed random numbers take the mean and standard deviation of the associated normal distribution as parameters.

My problem is that I only know the mean and the coefficient of variation of the lognormal distribution. It is reasonably straight forward to derive the parameters I need for the standard functions from what I have:

If `mu` and `sigma` are the mean and standard deviation of the associated normal distribution, we know that

``````coeffOfVar^2 = variance / mean^2
= (exp(sigma^2) - 1) * exp(2*mu + sigma^2) / exp(mu + sigma^2/2)^2
= exp(sigma^2) - 1
``````

We can rearrange this to

``````sigma = sqrt(log(coeffOfVar^2 + 1))
``````

We also know that

``````mean = exp(mu + sigma^2/2)
``````

This rearranges to

``````mu = log(mean) - sigma^2/2
``````

Here's my R implementation

``````rlnorm0 <- function(mean, coeffOfVar, n = 1e6)
{
sigma <- sqrt(log(coeffOfVar^2 + 1))
mu <- log(mean) - sigma^2 / 2
rlnorm(n, mu, sigma)
}
``````

It works okay for small coefficients of variation

``````r1 <- rlnorm0(2, 0.5)
mean(r1)                 # 2.000095
sd(r1) / mean(r1)        # 0.4998437
``````

But not for larger values

``````r2 <- rlnorm0(2, 50)
mean(r2)                 # 2.048509
sd(r2) / mean(r2)        # 68.55871
``````

To check that it wasn't an R-specific issue, I reimplemented it in MATLAB. (Uses stats toolbox.)

``````function y = lognrnd0(mean, coeffOfVar, sizeOut)
if nargin < 3 || isempty(sizeOut)
sizeOut = [1e6 1];
end
sigma = sqrt(log(coeffOfVar.^2 + 1));
mu = log(mean) - sigma.^2 ./ 2;
y = lognrnd(mu, sigma, sizeOut);
end

r1 = lognrnd0(2, 0.5);
mean(r1)                  % 2.0013
std(r1) ./ mean(r1)       % 0.5008

r2 = lognrnd0(2, 50);
mean(r2)                  % 1.9611
std(r2) ./ mean(r2)       % 22.61
``````

Same problem. The question is, why is this happening? Is it just that the standard deviation is not robust when the variation is that wide? Or have I screwed up somewhere?

-
If mu is the mean, why do you recalculate a mean? –  McThunderThighs Mar 26 '10 at 12:25
I believe the formulas are correct. If you calculate the population sd giving the formula my.sd <- sqrt(exp(sigma^2) - 1) * exp(mu + 1/2*sigma^2), for mean=2 and cv=50, you will get my.sd = 100 (correct). But R's sd function gave me values between 39 and 100 in subsequent runs. A very large standard error! –  George Dontas Mar 26 '10 at 12:31
@James: `mu` is the mean of the log of the data (not the mean of the data). I calculate the sample mean to check that it matches the theoretical mean that I want. –  Richie Cotton Mar 26 '10 at 13:03
@gd047: Thanks for checking the formulas. –  Richie Cotton Mar 26 '10 at 13:05

The results are not surprising. For distributions with large kurtosis, expected variance of the sample variance is roughly mu4/N, where mu4 is the 4th moment of the distribution. For a lognormal, mu4 exponentially depends on the parameter sigma^2, meaning that for large enough values of sigma, your sample variance will be all over the place relative to the true variance. This is precisely what you have observed. In your example, mu4/N ~ (coeffOfVar^8)/N ~ 50^8/1e6 ~ 4e7.

For derivation of the expected variance of sample var. see http://mathworld.wolfram.com/SampleVarianceDistribution.html. Below is some code to illustrate the ideas in a more exact manner. Note the large value of both the variance of the sample variance and its theoretical expected value, even for coeffOfVar = 5.

``````exp.var.of.samp.var <- function(n,mu2,mu4){
(n-1)*((n-1)*mu4-(n-3)*mu2^2)/n^3
}
mu2.lnorm <- function(mu,sigma){
(exp(sigma^2)-1)*exp(2*mu+sigma^2)
}
mu4.lnorm <- function(mu,sigma){
mu2.lnorm(mu,sigma)^2*(exp(4*sigma^2)+2*exp(3*sigma^2)+3*exp(2*sigma^2)-3)
}
exp.var.lnorm.var <- function(n,mu,sigma){
exp.var.of.samp.var(n,mu2.lnorm(mu,sigma),mu4.lnorm(mu,sigma))
}
exp.var.norm.var <- function(n,mu,sigma){
exp.var.of.samp.var(n,sigma^2,3*sigma^4)
}

coeffOfVar <- 5
mean <- 2
sigma <- sqrt(log(coeffOfVar^2 + 1)) # gives sigma=1.805020
mu <- log(mean) - sigma^2 / 2 # mu=-0.935901
n <- 1e4
m <- 1e4
## Get variance of sample variance for lognormal distribution:
var.trial <- replicate(m,var(rlnorm(n, mu, sigma)))
cat("samp. variance (mean of",m,"trials):",mean(var.trial),"\n")
cat("theor. variance:",mu2.lnorm(mu,sigma),"\n")
cat("variance of the sample var:",var(var.trial),"\n")
cat("expected variance of the sample var:",exp.var.lnorm.var(n,mu,sigma),"\n")
> samp. variance (mean of 10000 trials): 105.7192
> theor. variance: 100
> variance of the sample var: 350997.7
> expected variance of the sample var: 494053.2
## Do this with normal distribution:
var.trial <- replicate(m,var(rnorm(n, mu, sigma)))
cat("samp. variance (mean of",m,"trials):",mean(var.trial),"\n")
cat("theor. variance:",sigma^2,"\n")
cat("variance of the sample var:",var(var.trial),"\n")
cat("expected variance of the sample var:",exp.var.norm.var(n,mu,sigma),"\n")
> samp. variance (mean of 10000 trials): 3.257944
> theor. variance: 3.258097
> variance of the sample var: 0.002166131
> expected variance of the sample var: 0.002122826
``````
-
@Leo A: Thanks for this; I've learnt something new here. I think your lognormal numbers look odd because you've redefined `sigma` to be half what it should be (after the definitions of `n`, `m`). –  Richie Cotton Mar 26 '10 at 13:09
Correct me if I'm wrong but I think some points need double-checking. mu4.lnorm should be exp(4*sigma^2)+2*exp(3*sigma^2)+3*exp(2*sigma^2)-6 according to mathworld.wolfram.com/LogNormalDistribution.html. Also sigma shouldn't be multiplied by 0.5 and should be calculated before mu. You can find the formula for exp.var.of.samp.var here (7.4 on page 241) scribd.com/doc/24280430/Statistics-and-Data-With-R –  George Dontas Mar 26 '10 at 14:17
@gd047: good catch on mu4 (it was wrong -- I was mixing up variance of the normal and the lognormal -- but I don't think your version is correct either :) ). The numbers look better now. –  Leo Alekseyev Mar 26 '10 at 14:45
@Leo: If you are talking about the -6, it's just because it uses the excess kurtosis = m4/s^4 - 3 –  George Dontas Mar 26 '10 at 15:19
The formula you gave in the comment was actually m4/s^4 whereas m4 is needed, I believe. –  Leo Alekseyev Mar 26 '10 at 16:05