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# Generate a random number with max, min and mean(average) in Java

I need to generate random numbers with following properties.

Min should be 200

Max should be 20000

Average(mean) is 500.

Optional: 75th percentile to be 5000

Definitely it is not uniform distribution, nor gaussian. I need to give some left skewness.

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This is actually a delightful math problem. I think it has something to do with identifying a function whose integral over 0-300 matches its integral over 300-19800, but I don't know if I can get any further than that, myself! – Cephron Mar 15 '11 at 16:05
@Richard: even better: there's enough info to define any number of distributions! ;-) – Joachim Sauer Mar 15 '11 at 16:17
@Chuck: I can think of many uses of this that would not imply homework. It might be homework, but it can just as well not be. – Joachim Sauer Mar 15 '11 at 16:22
@Chuck: a monte-carlo simulation for some behaviour that has been observed to show these properties when measured. – Joachim Sauer Mar 15 '11 at 16:34
No this is not a homework. I am working on a prototype, that requires modeling such distribution. See for more info: wiki.mozilla.org/Socorro:ClientAPI – Fuad Malikov Mar 15 '11 at 16:47

Java Random probably won't work because it only gives you normal(gaussian) distributions.

What you're probably looking for is an f distribution (see below). You can probably use the distlib library here and choose the f distribution. You can use the random method to get your random number.

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An F distribution is not bounded, so you'd have to truncate it to fit the requirements - and that would complictate the computation of the parameters. – leonbloy Jun 9 '11 at 16:52
@leonbloy true it is infinite and not bounded, but you could get the probability so small in the right tail that even if you did happen to get a number past the max value, you can just call it the max value. (if > max then max). If you have a better solution, I think you should put it in an answer rather than pointing out flaws in this solution which I believe is valid with a simple check. I'd like to hear what other people have/would do for the question asked. – Scott Jun 9 '11 at 18:06
 I think you should put it in an answer rather than pointing out flaws in this solution Uh? Of course one MUST point out flaws or shortcomings in any answer here in SO, so that anyone (the OP or anyone) who is going to use it is aware! The goal here is not to compete, but to have a good repository of answers. It doesn't matter whether one has posted an answer of his own (which I have, BTW). – leonbloy Jun 9 '11 at 18:15
I see you posted an answer, which is good and an good answer. I just don't think a down vote for a simple truncation of an infinitely small upper value is warranted. There may be better solutions, which I think there probably are, but this one is not terrible with the caveat of upper bound truncation. – Scott Jun 9 '11 at 22:39
@Scott For the random function, though, don't you need to use an inverse function? As in, the inverse of the f distribution. From what little work I've done with random functions, that is what I had to find. In that case, you would need to look up the mathematics of the f distribution yourself and decide if it is easily invertible. If it is, easy. If it's not, you'll need to create large inverse tables from which you can determine the inverse function. Obviously, you can't write it for 0<x<1, so you'll need to pick an interval, say .001 and use extrapolation to fill in the holes – Ryan Amos Jun 14 '11 at 19:43

Say X is your target variable, lets normalize the range by doing Y=(X-200)/(20000-200). So now you want some Y random variable that takes values in [0,1] with mean (500-200)/(20000-200)=1/66.

You have many options, the most natural one seems to me a Beta distribution, Y ~ Beta(a,b) with a/(a+b) = 1/66 - you have an extra degree of freedom, which you can choose either to fit the last quartile requirement.

After that, you simply return X as Y*(20000-200)+200

To generate a Beta random variable, you can use Apache Commons or see here.

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This may not be the answer you're looking for, but the specific case with 3 uniform distributions:

(Ignore the numbers on the left, but it is to scale!)

public int generate() {
if(random(0, 65) == 0) {
// 50-100 percentile

if(random(1, 13) > 3) {
// 50-75 percentile
return random(500, 5000);
} else {
// 75-100 percentile
return random(5000, 20000);
}

} else {
// 0-50 percentile
return random(200, 500);
}
}


How I got the numbers

First, the area under the curve is equal between 200-500 and 500-20000. This means that the height relationship is 300 * leftHeight == 19500 * rightHeight making leftHeight == 65 * rightHeight

This gives us a 1/66 chance to choose right, and a 65/66 chance to choose left.

I then made the same calculation for the 75th percentile, except the ratio was 500-5000 chance == 5000-20000 chance * 10 / 3. Again, this means we have a 10/13 chance to be in 50-75 percentile, and a 3/13 chance to be in 75-100.

Kudos to @Stas - I am using his 'inclusive random' function.

And yes, I realise my numbers are wrong as this method works with discrete numbers, and my calculations were continuous. It would be good if someone could correct my border cases.

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You can have a function f working on [0;1] such as

Integral(f(x)dx) on [0;1] = 500
f(0) = 200
f(0.75) = 5000
f(1) = 20000


I guess a function of the form

f(x) = a*exp(x) + b*x + c


could be a solution, you just have to solve the related system.

Then, you do f(uniform_random(0,1)) and there you are !

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