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# how to generate random numbers with lognormal distribution and with specified geometric mean and geometric standard deviationin Matlab

I would like to generate some random numbers log-normally distributed with a specified geometric mean (GM) and geometric standard deviation (GSD), say GM=10 and GSD=2.5. How do I do that in Matlab? I looked up Matlab's help and found this link but I want to use my initial inputs as GM and GSD rather than mean and variance.

http://www.mathworks.com/help/toolbox/stats/lognrnd.html

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You may get a better audience at the math version of this site here. – Jeff Wolski Dec 2 '11 at 6:09
Or the stats version [here](stats.stackexchange.com). – Sam Roberts Dec 2 '11 at 9:11

Wikipedia says that the geometric mean of the log-normal distribution is exp(µ) and the geometric standard deviation is exp(sigma). So just do:

rn = lognrnd(log(GM), log(GSD));
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Thank you Silvado. This code worked! – user1009166 Dec 2 '11 at 17:15

Difficult to write as stackoverflow doesn't have maths markup (might be some LaTeX mistakes below), but if we define $m_a$ and $m_g$ as the arithmetic and geometric means, and $s_a$ and $s_g$ as the arithmetic and geometric standard deviations:

$m_a = exp(\mu + \sigma^2/2),$

$m_g = m_a exp(-\sigma^2/2),$

and

$s_g = exp(\sigma) <-> \sigma = log(s_g)$

If $m_g = 10$, $m_a = 10/\exp(-\sigma^2/2) = 10/\exp(-\log(s_g)^2/2)$, and

$s_g = (\exp(\sigma^2)-1)\exp(\mu \s_g = \exp(\mu + \sigma^2/2)\sqrt{\exp(\sigma^2 - 1)} .$

So:

GM = 10; GSD = 2.5;
M = 10/exp(-log(GSD)^2/2);
V = exp(log(GM)+log(GSD)^2/2)*sqrt(exp(log(GSD)^2)-1);
MU = log(M^2 / sqrt(V+M^2))
SIGMA = sqrt(log(V/M^2 + 1))

>> lognrnd(MU, SIGMA, 10, 1)

ans =

18.5128
15.9902
10.3143
13.0549
16.0934
38.5006
30.9571
10.1976
33.2538
17.8427
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Note that the parameters mu and sigma in lognrandn are the arithmetic mean and standard deviation of the associated normal distribution (not the generated log-normal distribution). In particular, the distribution generated with the suggested approach will not have 10 as geometric mean (observe that from the 10 samples, none is smaller than 10). – silvado Dec 2 '11 at 13:21
Thank you tdc for your answer. I checked numbers generated by your approach and the GM is indeed greater than 10. – user1009166 Dec 2 '11 at 17:17
Ah sorry - decidedly unhelpful paramterisation from matlab I'd say! – tdc Dec 4 '11 at 19:34