# Monte Carlo Simulation in Excel for Non-normal Distributions

I would like to simulate the performance a baseball player. I know his expected performance for every future year and the standard deviations of those performances (based on regression analysis). At first, I was thinking of using the NORMINV(RAND(),REF,REF) function in excel, but the underlying distribution of baseball players' performances is dramatically right skewed. Is there a way that I can perform this sort of analysis in Excel or some other free or low-cost software? The end-goal here is for the simulation to use the right skewed distribution. Thanks very much.

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Have you looked at a histogram of your regression residuals? You might be able to pick a strong contender for the distribution from some of the popular skewed distributions, such chi-squared, exponential, gamma, log-normal, etc. Since residuals are centered at zero, you might need to do some shifting... –  pjs Jul 24 '13 at 0:02

R has lots of tools to do this sort of analysis, though you'd have to look through the docs to figure out how to use it. R is free, at least for non-commercial use.

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R is licensed under the GPL, so it should be free for commercial use too. You might also want to link to r-project.org, although, surprisingly, it turns out the searching Google for "R" does actually return that page as one of the first results. –  Ilmari Karonen Jul 24 '13 at 0:02
Thanks, Joel. I don't have any experience with R. I am a VBA/SQL guy. You think it's reasonably intuitive or does it take a significant investment of time and energy just to look single-variate non-normal data? –  user2612534 Jul 24 '13 at 0:07
For a script programmer the language isn't too bad, but the math can be hard no matter what language you use. –  Joel Jul 24 '13 at 6:26

If you have a cumulative distribution table (that is evenly spaced and sufficiently detailed) then you can easily generate random values from this distribution in Excel by looking up a uniform random number generated by `RAND()` in your distribution table and take the corresponding "x-axis" value.

``````=OFFSET(\$A\$1,MATCH(RAND(),\$B\$2:\$B\$102),0)
``````

A1 is the cell just above the table of "x-axis" values.
B2:B102 is the cumulative distribution table.

This is a simplified example. Some small modifications may be needed to handle edge-cases and adjust for biases.

If you have enough empirical data you should be able to create the cumulative distribution table.

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