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I seem to be having a bit of an issue understanding this Perlin Noise article. I need some help understanding how calculating the pseudorandom gradients for each bounding point works. The author gives the function:

g(xgrid, ygrid) = (gx, gy)

Then he gives the image:

4 pseudorandom gradients?

I understand the rest of the article, but I have no idea how he generates these random gradients from each bounding point. Assistance would be greatly appreciated. Thanks!

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1 Answer 1

up vote 1 down vote accepted

but I have no idea how he generates these random gradients from each bounding point.

From the article, it uses a pseudorandom number generator with always the same seed, and calculates it always on the same grid, so that

we mean that g has the appearance of randomness, but with the important consideration that it always returns the same gradient for the same grid point, every time it's calculated. It's also important that every direction has an equal chance of being picked.

So probably it does something like


for (y = 0; y < GridHeight; y++)
    for (x = 0; x < GridWidth; x++)
        r1 = rand();
        r2 = rand();
        gradient[y][x] = some_function(r1, r2);

so that in each point the gradient is pseudorandom, it is always the same for the same x and y, and is distributed evenly. It then accesses the matrix gradient to run the rest of the calculations.

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Good answer but in all the implementations of Perlin Noise I've seen, nothing like that has been used. 'Gradients' don't seem to be true gradients. But I am not sure. –  MrDoctorProfessorTyler Nov 22 '12 at 14:55
Agree that they don't look much like gradients - I'd call them rather vectors. Or even versors, they look like they're fixed length. Still, that's what HE said :-D –  lserni Nov 22 '12 at 21:55
I think they're gradients in the sense that they represent the rate of change of the noise at that point, like a "normal" vector. Fixed-length is what helps the maxima of the noise to be consistent. If they were truly random the noise would have dull spots. I think. –  James Clark Feb 12 '13 at 3:40

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