# Generation of uniformly distributed random noise

I've been working on generating Perlin noise for a map generator of mine. The problem I've run into is that the random noise is not distributed normally, and is more likely a normal distribution of kinds.

Given two integers X and Y, and a seed value, I do the following:

• Use MurmurHash2 to generate a random number (-1,1). This is uniformly distributed.
• Interpolate points between integer values with cubic interpolation. Values now fall in the range (-2.25, 2.25) because the interpolation can extrapolate higher points (by 1.5 in every dimension) between similar values, and the distribution is no longer uniform.
• Generate these interpolated points, summing them together while halving the amplitudes (See: Perling noise) As the number of sums approaches infinity, the limit of the range now approaches twice the previous values, or (-4.5, 4.5) and is now even less uniform.

This obviously doesn't work when I want a range from (-1, 1), so I divide all final values by 4.5. Actually, I divide them along the way (by 1.5 after interpolating each dimension, then by 2 after summing the noise.)

After the division, I'm left with a theoretical range of (-1, 1). However, the vast majority of the values are (-0.2,0.2). This doesn't work well when generating my maps, since I need to determine the percentage of the map filled. I also cannot use histograms to determine what threshold to use, since I'm generating the squares on demand, and not the entire map.

I need to make my distribution uniform at two points - after the interpolation, and after the summing of the noise functions. I'm not sure how to go about this, tho.

My distribution looks like this:

I need it to look like this:

(Both images from Wikipedia.)

Any solutions are appreciated, but I'm writing in C#, so code snippets would be extremely helpful.

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Sorry, I don't fully understand your question: you want someone to help you debug your algorithm, or a Normal[mu,sigma] random number generator? – Dr. belisarius Sep 12 '10 at 21:48
No, my algorithm works like it should, just not how I want it to. And I don't want to generate a random normal distribution. I want to take my algorithm, which generates a random normal distribution (-4.5,4.5) and make it generate a uniform distribution (-1,1). – dlras2 Sep 12 '10 at 21:49
You have a uniform (-1,1) distribution already at step 1... – Keith Randall Sep 12 '10 at 22:00
@Keith - Yes, but I don't have a Perlin noise function. Just completely random noise, which is useless in generating natural clumping, etc. (See the first link.) – dlras2 Sep 12 '10 at 22:01
So you want the individual "points" in your final Perlin-noise-shaped function to have a random distribution instead of the normal distribution? And do this while still having a perlin-shaped map? – Justin L. Sep 12 '10 at 22:19

Combine the resulting sample with the CDF for the gaussian, which is 0.5*erf(x) + 1 (erf = error function).

Note that in virtue of the Central Limit Theorem, whenever you make sums of random variables, you get gaussian laws.

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I think this is the right answer, but I'm having trouble coming up with the error function. The mean is obviously zero, but how do I determine the variance? I know the middle 50% of my distribution falls between about (-.4,4), with a maximum value at 1.672 and a minimum at -1.734 (calculated after taking a billion samples.) – dlras2 Sep 13 '10 at 13:43
cdf = 0.5 + 0.5 * erf((x - mu) / (sqrt(2 * variance))). You have to determinate the variance empirically (google empirical variance estimator) – Alexandre C. Sep 13 '10 at 17:14

This is a simple scaling problem. And all simple scaling problems are just manifestations of a straight line in Cartesian geometry:

You have a line:

``````       |   /
1 + -/,
| / ,
____,__|/__,____
-4.5 /|   4.5
,/ |
/- + -1
/   |
``````

on that line, when x=4.5, y=1 and when x=-4.5 y=-1. Now I'm sure that once you realize this you know the solution. `y=mx + c`. Since the line is symmetric on both positive and negative sides then you can assume that it crosses at zero so `c=0`. Now to find the slope:

``````m = dy/dx
m = (1 - -1)/(4.5 - -4.5)
m = 2/9
``````

therefore:

``````y = 2/9 x + 0
y = 2x / 9
``````

so, now you can plug this in. What is y when x = 3?:

``````y = 2*3 / 9
y = 6/9
y = 2/3
``````

and what is y when x = 4?:

``````y = 2*4 / 9
y = 8/9
``````

The assume-the-line-crosses-at-zero thing I'm doing because my experienced eye tells me it's right. But if I were doing this for a high school math exam I'd likely lose credits (even if my answer is right). For the proper formulaic solution, to find `c` you have to first find `m` and then substitute the `x` and `y` values of a known coordinate:

``````y = 2/9 x + c
``````

given that (4.5,1) and (-4.5,-1) are known coordinates, substitute x and y for 4.5 and 1:

``````1 = 2*4.5/9 + c
1 = 9/9 + c
1 = 1 + c
c = 1 - 1
c = 0
``````

All this can be enshrined in a scaling function:

``````// example code in javascript:
function makeScaler (x1, y1, x2, y2) {
var m = (x2-x1)/(y2-y1);
var c = y1 - m*x1;

// return a scaling function:
return function (x) {
return m*x + c;
}
}

var f = makeScaler(-4.5,-1,4.5,1);
alert(f(4)); // what y is when x is 4

// or if you prefer:
var g = makeScaler(-4.5,0,4.5,1); // scale from 0 to 1