Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to implement some source code I found online to generate a height map using Perlin Noise. I've successfully managed to get the height map, using the noise3 function with the third coordinate being a random "seed," to allow for random height maps.

My problem is that the terrain generated is rather dull, I want mountains and I'm getting rolling grassland. I've done some reading up on Perlin Noise (mostly here). Due to the source code I've found obviously not written with readability in mind and my weak grasp on the concept of Perlin Noise in general, I can't figure out what I need to tweak in the code (amplitude and frequency?) to create more drastic terrain.

Some more info on generating height maps using Perlin Noise, Perlin Noise in general or even some more decipherable code would also be welcome.

EDIT: I understand (kindof) how Perlin Noise works, eg: with respect to amplitude and frequency, I'm just wondering what variables to change in the code I linked above are used for these two aspects.

share|improve this question
Does the attached code help? –  gamernb Jan 21 '11 at 19:07
Plain Perlin noise ("1 layer of noise") is boring. What you're looking for is commonly called "fractal brownian motion noise" (fBm), where you add Perlin noise of different frequencies together. See here for great definitions of lacunarity, frequency, octave wrt Perlin fractal noise –  bobobobo Dec 22 '12 at 14:21

4 Answers 4

up vote 44 down vote accepted

Perlin noise is completely controlled by the different variables you set, i.e. amplitude, frequency and persistance. The amount of octaves has a little change, but not much. In code that I have written in the past I have just played around with the order of magnitude of the frequency and persistance until I have gotten what I needed. I can try to find my old source if needed.


#pragma once

class PerlinNoise

  // Constructor
    PerlinNoise(double _persistence, double _frequency, double _amplitude, int _octaves, int _randomseed);

  // Get Height
    double GetHeight(double x, double y) const;

  // Get
  double Persistence() const { return persistence; }
  double Frequency()   const { return frequency;   }
  double Amplitude()   const { return amplitude;   }
  int    Octaves()     const { return octaves;     }
  int    RandomSeed()  const { return randomseed;  }

  // Set
  void Set(double _persistence, double _frequency, double _amplitude, int _octaves, int _randomseed);

  void SetPersistence(double _persistence) { persistence = _persistence; }
  void SetFrequency(  double _frequency)   { frequency = _frequency;     }
  void SetAmplitude(  double _amplitude)   { amplitude = _amplitude;     }
  void SetOctaves(    int    _octaves)     { octaves = _octaves;         }
  void SetRandomSeed( int    _randomseed)  { randomseed = _randomseed;   }


    double Total(double i, double j) const;
    double GetValue(double x, double y) const;
    double Interpolate(double x, double y, double a) const;
    double Noise(int x, int y) const;

    double persistence, frequency, amplitude;
    int octaves, randomseed;


#include "PerlinNoise.h"

  persistence = 0;
  frequency = 0;
  amplitude  = 0;
  octaves = 0;
  randomseed = 0;

PerlinNoise::PerlinNoise(double _persistence, double _frequency, double _amplitude, int _octaves, int _randomseed)
  persistence = _persistence;
  frequency = _frequency;
  amplitude  = _amplitude;
  octaves = _octaves;
  randomseed = 2 + _randomseed * _randomseed;

void PerlinNoise::Set(double _persistence, double _frequency, double _amplitude, int _octaves, int _randomseed)
  persistence = _persistence;
  frequency = _frequency;
  amplitude  = _amplitude;
  octaves = _octaves;
  randomseed = 2 + _randomseed * _randomseed;

double PerlinNoise::GetHeight(double x, double y) const
  return amplitude * Total(x, y);

double PerlinNoise::Total(double i, double j) const
    //properties of one octave (changing each loop)
    double t = 0.0f;
    double _amplitude = 1;
    double freq = frequency;

    for(int k = 0; k < octaves; k++) 
        t += GetValue(j * freq + randomseed, i * freq + randomseed) * _amplitude;
        _amplitude *= persistence;
        freq *= 2;

    return t;

double PerlinNoise::GetValue(double x, double y) const
    int Xint = (int)x;
    int Yint = (int)y;
    double Xfrac = x - Xint;
    double Yfrac = y - Yint;

  //noise values
  double n01 = Noise(Xint-1, Yint-1);
  double n02 = Noise(Xint+1, Yint-1);
  double n03 = Noise(Xint-1, Yint+1);
  double n04 = Noise(Xint+1, Yint+1);
  double n05 = Noise(Xint-1, Yint);
  double n06 = Noise(Xint+1, Yint);
  double n07 = Noise(Xint, Yint-1);
  double n08 = Noise(Xint, Yint+1);
  double n09 = Noise(Xint, Yint);

  double n12 = Noise(Xint+2, Yint-1);
  double n14 = Noise(Xint+2, Yint+1);
  double n16 = Noise(Xint+2, Yint);

  double n23 = Noise(Xint-1, Yint+2);
  double n24 = Noise(Xint+1, Yint+2);
  double n28 = Noise(Xint, Yint+2);

  double n34 = Noise(Xint+2, Yint+2);

    //find the noise values of the four corners
    double x0y0 = 0.0625*(n01+n02+n03+n04) + 0.125*(n05+n06+n07+n08) + 0.25*(n09);  
    double x1y0 = 0.0625*(n07+n12+n08+n14) + 0.125*(n09+n16+n02+n04) + 0.25*(n06);  
    double x0y1 = 0.0625*(n05+n06+n23+n24) + 0.125*(n03+n04+n09+n28) + 0.25*(n08);  
    double x1y1 = 0.0625*(n09+n16+n28+n34) + 0.125*(n08+n14+n06+n24) + 0.25*(n04);  

    //interpolate between those values according to the x and y fractions
    double v1 = Interpolate(x0y0, x1y0, Xfrac); //interpolate in x direction (y)
    double v2 = Interpolate(x0y1, x1y1, Xfrac); //interpolate in x direction (y+1)
    double fin = Interpolate(v1, v2, Yfrac);  //interpolate in y direction

    return fin;

double PerlinNoise::Interpolate(double x, double y, double a) const
    double negA = 1.0 - a;
  double negASqr = negA * negA;
    double fac1 = 3.0 * (negASqr) - 2.0 * (negASqr * negA);
  double aSqr = a * a;
    double fac2 = 3.0 * aSqr - 2.0 * (aSqr * a);

    return x * fac1 + y * fac2; //add the weighted factors

double PerlinNoise::Noise(int x, int y) const
    int n = x + y * 57;
    n = (n << 13) ^ n;
  int t = (n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff;
    return 1.0 - double(t) * 0.931322574615478515625e-9;/// 1073741824.0);
share|improve this answer
Thanks for posting this source! –  slycrel Apr 14 '11 at 20:00
I wrote it quite a while back. I'm glad someone could find some use of it. –  gamernb Apr 14 '11 at 20:17
great post! This helped turn my own boring rolling hills into awesome looking mountain ranges! Perlin noise is awesome! thanks! –  Nitrex88 Jul 6 '11 at 8:25
Sure. Do what you want with the code. –  gamernb Aug 10 '11 at 3:46
I hate blackboxes –  jokoon May 27 at 21:28

A friend just linked me to this question, and I thought I'd try and clear up a couple things that aren't addressed in the accepted answer.

Elias' interesting and helpful article uses "value noise" not "gradient noise". Value noise involves curve-fitting of randomized points. Gradient noise creates a lattice of 0-value points and gives each one a random gradient. They are frequently confused with one another!


Secondly, using a 3rd value as a seed is expensive. If you want random terrain, consider translating your origin a random amount instead. 3D calls are going to be more expensive than 2D calls. And all you are doing is using the z value to select a particular slice of 2D noise.

Thirdly, the straight function call is going to return values that are fairly smooth and rolling overall, not as craggy as real terrain, since it's randomness is limited to a single frequency. To get craggier terrain, a good technique is to sum together multiple calls that progress through the noise space at differing frequencies, usually set a "fractal" values.

Thus, for example, sum together noise(x, y) + (1/2)(noise(x*2, y*2) + (1/4)(noise(x*4, y*4)...

The resulting sum will probably often be outside the range -1 to 1, so you will have to normalize the result before the values are useful. I'd like to suggest setting up the factor series (1, 1/2, 1/4, etc.) so that you are guaranteed to remain within [-1, 1] which can be done by progressive weighting depending upon how many 'octaves' you use. (But I don't know if this is truly the most efficient way to do this.)

Example with four octaves: (1/15)(noise(x, y) + (2/15)(noise(2x, 2y) + (4/15)(noise(4x, 4y) + (8/15)(noise(8x, 8y)

Then, use the "turbulent noise" normalization of taking the sum and making it = |sum| (i.e., using the abs function). This will give the terrain definite angular valley ridges as opposed to being smoothly rolling.

I'm working on a SimplexNoise visualizer, hope to open source it on GitHub eventually, as a Java project. A first draft of the visualizer can be found and run via this post at java-gaming.org: http://www.java-gaming.org/topics/simplex-noise-experiments-towards-procedural-generation/27163/view.html The emphasis on the first draft is more tutorial, with generated code examples (but they are in Java).

Great article on how SimplexNoise works (and Perlin vs Gradient background): http://staffwww.itn.liu.se/~stegu/simplexnoise/simplexnoise.pdf

Stefan Gustavson did a really nice job of this!

share|improve this answer

Amplitude controls how high/low the terrain is, the frequency how flowing it is, with lower frequency being more flowing.

So if you want a jagged mountainous landscape you need to up both.

share|improve this answer
Hi, what are the ranges for the different values? For example, is amplitude a value between zero and one? Thanks –  user291701 Aug 24 '12 at 21:11
That fully depends on the implementation you are working with. –  wich Sep 10 '12 at 1:53
He may want ballpark figures to get started -- if so: 2-6 for frequency good for small terrains, octaves 1-16 is fine, amp is just a normalized field. I generate a city and choose buildings based on it for a 32x32 grid, and find these ranges are fine...freq 5+ gives me better results for what I'm doing. –  SinisterRainbow Dec 1 '12 at 23:57

Here's an example of surface generation I wrote a while ago in JavaScript using 3D Perlin Noise. Since in a surface voxels are either present or not I simply apply a threshold after calculating the Perlin Noise cube. In the example the noise probability is equal for all dimensions. You can get a more realistic landscape when you increase the random values towards the ground and reduce it towards the sky.


WebGL must be enabled. At the time of writing this I recommend to use Chrome for best performance.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.