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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:

Normal distribution

I need it to look like this:

Uniform distribution

(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? –  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

3 Answers 3

up vote 2 down vote accepted

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

additional notes:

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
alert(g(4));
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This does not answer my question. Were the distribution already uniform (a straight line) then I wouldn't have a problem. I'm trying to force a curvy line onto a straight one. –  dlras2 Sep 13 '10 at 0:47
    
@Daniel A picture of the transformation you are looking for could be useful –  belisarius Sep 13 '10 at 0:51
    
@belisarius - I'm not actually sure how I would get a picture of the distribution. Basically, I'm just looking for a way to scale a normal distribution into a uniform one. –  dlras2 Sep 13 '10 at 0:54
    
This answers your question. The straight line is NOT the DISTRIBUTION but the MAPPING. MAPPINGS are linear. –  slebetman Sep 13 '10 at 1:01
    
Let's try this before you refuse to believe my correct answer: generate the distribution and dump it to a file. Then apply the linear mapping function and dump it to another file. Plot it. You will see that the original distribution and the linearly scaled distribution are the same except for the values being scaled. –  slebetman Sep 13 '10 at 1:03

This is an answer to your final comment, rather than your question as asked. I don't necessarily think you can scale your resulting distribution back into a uniform distribution, and I'm not sure you would want to if you could. But if your goal is to get, say, all the values under 50% to be grass, it may be easier and less error prone to measure (or estimate) the median of your output, and call that 50%.

The result is the same, and you don't have to deal with any complicated (and therefore error-prone) scaling functions.

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