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I implemented bilinear interpolated white noise in order to procedurally generate terrain.

I can obtain this kind of result:

enter image description here

I would like to implement ridged fractal noise to get a more realistic terrain like:

enter image description here

However I can't find a good tutorial for ridged fractal noise. Can you explain to me how to do this?

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  • Hi :) Thank you for helping. I Think it's a modification to the noise function in order to have ridges. I think it's ridged fractal noise. But I can't find the changes i have to do on my noise to get something like this. On a site somebody tells it's only the noise chanded with an absolute valued function. But i don't see how to use an absolute valued function to change my noise output :s
    – JimZer
    Apr 24, 2016 at 16:33
  • Not clear to me how to use absolute value to get that effect; I have heard of using a clamping function to get terraces though.
    – Pikalek
    Apr 24, 2016 at 18:00
  • Just an idea, but instead of using straight (bi)linear interpolation, apply a sigmoid-type function to the value of x before passing it into the A * (1 - x) + B * x linear interpolation function
    – Alnitak
    Apr 25, 2016 at 14:36

2 Answers 2

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Ridged perlin noise is actually fairly easy to do - you just have to ABS() either the final heightmap or some subset of the noise layers (and then invert the resulting height map values, to make sure the ridge occurs at the high values).

Example: enter image description here (basic perlin noise with trilinear interpolation followed by ABS and INVERT of the entire height field). (INVERT means "multiply by -1".)

I highly recommend experimenting with various configurations of fractal noise layers and basic mathematical/logical operations.

Another example: enter image description here (two different low frequency perlin noise layers merged using a logical INTERSECTION / math MINIMUM function)

However, no simple modification to a fractal noise algorithm will give you those details that appear to "flow downhill" (and make the terrain much more realistic and appealing). To achieve those, you will need to add some kind of erosion simulation, which is a much more complex beast (both algorithm-wise and CPU-wise).

For some information on that, I recommend these two papers (you can ignore the GPU part, the algorithms work fine on CPU, although in my experience the simulation will take a minute or so for a 1000x1000 px image):

  1. Mei, Xing, Decaudin, Philippe and Hu, Bao-Gang. Fast Hydraulic Erosion Simulation and Visualisation on GPU. 2007.
  2. Fast Hydraulic and Thermal Erosion on the GPU. Jákó, Balász. 2011. The 15th Central European Seminar on Computer Graphics.

EDIT:

Let's clarify what I mean by "apply ABS on the height field".

You simply grab numeric value of height in each pixel of the map and apply the ABS () function on it, discarding its sign.

That assumes that the perlin noise generator generates the values in range <-1,1> (or another range centered on 0). ~50% of the pixels are expected to have value greater than 0 and ~50% are expected to have value less than 0.

The ABS causes sharp ridges to be created where the 0 is, since all the bilinear/trilinear interpolation would make sure that there used to be a smooth slope passing through the 0 value.

Consider this image:

enter image description here

It shows two COS(x) functions, one of which was modulated with an ABS function (I have added a small offset to make sure both lines are visible separately). Now imagine that the purple line is flipped vertically - you end up with two mountains with sharp ridges and a valley in between:)

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In order to produce physically realistic ridges, modifying the noise function is, as the previous answer stated, probably not the best way to go. Instead, if you start off with your fractal surface, and apply a decent erosion function to it, you can create ridged mountains with physically realistic shapes fairly easily.

I've recently written up my efforts along these lines on my website here: https://fractal-landscapes.co.uk/maths.html

The picture shows a comparison between the traditional thermal erosion model and subtractive-only erosion, which is what you want for ridges

Essentially, if your goal is simply ridges, you can modify the thermal erosion equation to remove all deposition (i.e. do subtractive-only erosion). I'm including the C# code I use to erode a single point - it's fairly fast, and will erode my 4096x4096 test landscape with 250 iterations in around 10 seconds on my PC (albeit with some parallelisation over 12 cores).

The messing around with bits is just an efficient way of getting the 8 neighbouring points of the point being eroded - my representation uses a linear array, so the y-coordinates are pre-multiplied by the width of the landscape (yMul etc...). You can treat stride as 1 for the purposes of simplicity. The r2demon and bit shift is just a fast multiplication by 1/sqrt(2) for the corner points.

var x0 = (x1 - stride) & mask;
var x2 = (x1 + stride) & mask;
indices[0] = x0 + yMul0;
indices[1] = x1 + yMul0;
indices[2] = x2 + yMul0;
indices[3] = x0 + yMul1;
indices[4] = x2 + yMul1;
indices[5] = x0 + yMul2;
indices[6] = x1 + yMul2;
indices[7] = x2 + yMul2;

for (int i = 0; i < actualLength; i++)
{
    elements[i] = thisSurface[indices[i]];
}

var height = thisSurface[x1 + yMul1];

//Differences in height.
//Corner differences multipled by 1/sqrt(2)
diffs[0] = ((height - elements[0]) * r2denom) >> 8;
diffs[1] = height - elements[1];
diffs[2] = ((height - elements[2]) * r2denom) >> 8;
diffs[3] = height - elements[3];
diffs[4] = height - elements[4];
diffs[5] = ((height - elements[5]) * r2denom) >> 8;
diffs[6] = height - elements[6];
diffs[7] = ((height - elements[7]) * r2denom) >> 8;

//Compare the differences to the talus threshold.
var max = 0;
var talusSum = 0;
var slopeSum = 0;
for (var i = 0; i < actualLength; i++)
{
    var diff = diffs[i];
    if (diff > 0)
    {
        if (diff > max)
        {
            max = diff;
        }

        talusSum += diff;
        if (diff > talusThreshold)
        {
            slopeSum += (diff - talusThreshold);
        }
    }
}

talusSum = talusSum / 2 - talusThreshold;

if (talusSum > 0)
{
    //Work out how much height to redistribute.
    var toMove = talusSum / 4;
    if (altitudeProportional)
    {
        toMove *= (height - minAltitude);
        toMove /= (maxAltitude - minAltitude);
    }

    newSurface[x1 + yMul1] -= toMove;
}
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