# Random numbers with non-uniform discrete densities

Just wondering what type of algorithm this is,

Say we are given a certain probability density, say

``````prob[] = {.1, .15, .25, .05, .45}
``````

Group 1 - 10%
Group 2 - 15%
Group 3 - 25%
Group 4 - 5%
Group 5 - 45%

and a random number, (0,1),
ran = .853234

Insert into one of the 5 groups

``````if (ran <=prob[0]) selection = 1;
else if (ran <= prob[0]+prob[1]) selection = 2;
...
else if (ran <= prob[0]+prob[1]+...+prob[4]) selection = 5;
``````

I am not very well-versed on random number generation

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What you are essentially doing here is inverting the cumulative distribution function. Let `F` be the CDF of a random variable `X` with a given distribution, then it is defined as `F(x) == P[X <= x]`.

The very useful thing here, is that if you generate a uniform random variable `U` between 0 and 1, then

``````P[F^-1(U) <= x] == P[U <= F(x)] == F(x) == P[X <= x]
``````

which means that `F^-1(U)` will have the same distribution as `X`!

Of course this is only possible if you can invert the CDF, but in your case `F`is a piecewise function (like a staircase), and your algorithm determines, for a given uniform value, at which step this value is met. Your algorithm is therefore perfectly correct.

However, you could improve it if you have a lot of random numbers to generate: first generate the CDF table, which in your case would be

``````CDF[] = {.1, .25, .5, .55, 1.}
``````

then for each generated uniform number between 0 and 1, simply perform a dichotomy on the CDF table to retriver the corresponding index.

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That code will work except that you probabilities don't add up to 100% (so it is possible for none of the if-statements to match).

The approach can be simplified a bit by using a cumulative probability distribution:

``````cumprob[5] = {.1, .2, .45, .50, 1.0};
``````

That also lets you substitute lsearch for the if-elif chain.

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Your algorithm uses random floating point numbers for a discrete distribution which is not the best way to implement this. Your implementation may provide a distribution hardly distinguishable from the given distribution, but it is not scientifically correct.

Instead, find the lowest common denominator of your given probabilities (in your example 5%) and use a random integer in [0,19] to pick your group. Example:

``````switch(random(19)) {
case 0:
case 1:
selection = 1;
break;
case 2:
case 3:
case 4:
selection = 2;
break;
case 5:
case 6:
case 7:
case 8:
case 9:
selection = 3;
break;
case 10:
selection = 4;
break;
case 11:
case 12:
case 13:
case 14:
case 15:
case 16:
case 17:
case 18:
case 19:
selection = 4;
break;
}
``````
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