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So I read up this article: http://www.wikihow.com/Plot-the-Mandelbrot-Set-By-Hand But I'm stuck at step 7. I'm drawing the set in javascript canvas.

All I need is basicly the C value I guess.

for (var y = 0; y < ImageHeight; y++) {
    for (var x = 0; x < ImageWidth; x++) {

        // Pixel-Position for ImageObject
        var xy = (x + y * image.width) * 4;

        // Convert Image-Dimension to a radius of 2
        var xi = ((x / ImageWidth) * 4) - 2;
        var yi = ((y / ImageHeight) * 4) - 2;

        for (var n = 0; n < MaxIterations; n++) {

            // Complex number stuff..?
            z = (xi*xi) + (yi*yi) + c;
            c = 0; // Somethig with z ..?

            if (z < 4) {

                image.data[xy] = inner_color[0];
                image.data[xy+1] = inner_color[1];
                image.data[xy+2] = inner_color[2];
                image.data[xy+3] = Math.round(n * cdiff);

            } else {

                image.data[xy] = outer_color[0];
                image.data[xy+1] = outer_color[1];
                image.data[xy+2] = outer_color[2];
                image.data[xy+3] = Math.round(n * cdiff);

                break;
            }
        }
    }
}

I also read up a lot about imaginary numbers and stuff, but I didn't quite understood how to calculate with them. And they seem somehow useless to me because you'd have to convert them back to real numbers anyways to do logic operations in javascript for example.

Here is what it looks like: http://elias-schuett.de/canvas/fractal2/ If you remove the 2 at the end of the url, you see another version where I just rewrote a little c++ snippit. But zooming is somehow weird, which is why I want to write it all on my own..

I understood the basic concept of the mandelbrot set creation but as I said the complex part is troubling me. Is there maybe an even simpler explanation out there ?

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Nope, every implementation of Mandelbrot uses complex numbers, because it's a figure in the complex plane. –  duffymo Feb 12 '12 at 22:14
    
But the complex plane looks just like a normal coordinate plane to me, so why calling it complex ? –  Elias Schütt Feb 12 '12 at 22:17
    
(sigh) You sound like to need to know something about complex numbers. If you did, the answer would be obvious. The real part of a complex number is the x-coordinate, the imaginary part is the y-coordinate. –  duffymo Feb 12 '12 at 23:09
    
Yeah I knew that. I also know how to add/multiply complex numbers. I just don't know how to use them in programming languages, since you can't calculate stuff with a string of "2i" for example.. none of the tutorials I read/watched explained that part. –  Elias Schütt Feb 13 '12 at 9:32
    
Write your own Complex class and see where that takes you. Start with that. –  duffymo Feb 13 '12 at 10:09

1 Answer 1

up vote 9 down vote accepted

You have to understand this first:

z = z^2 + c

Let's break it down.

Both z and c are complex numbers (and a recent question taught me, they have fractional digits, and can look like this: c=-0.70176-0.3842i). Complex numbers can have a part that is 'not real', the proper term is imaginary part, and you write a single complex number in the form:

(a + bi) which is the same as: (a + b*i)

If b is 0, then you have a a + 0i which is simply a so without an imaginary part you have a real number.

Your link does not mention the most important property of a complex number, especially a property of its imaginary part that i == sqrt(-1). On the field of Real numbers there is no such thing as a square root of a negative number and that's where complex numbers come in and allows you to have the square root of -1. Let's raise i to the power of 2: i^2 == -1, magick!

In a computer program you don't have such markers as i. You have to store the value in a variable, and have to you know how to handle that variable.

Now back to expanding z^2:

z == (a+bi), therefore z^2 == (a+bi)^2 so z^2 == (a^2 + bi^2 + 2*a*bi).

Let's break it down:

  • a^2 => this is simple, it is a real number
  • bi^2 => The tricky part. This is really b^2*i^2. And we got here an i^2, which is -1 and that makes it b^2*-1 or : -b^2.
  • 2*a*b*i => this will be the imaginary part

Result: z^2 = (a^2-b^2+2*a*bi)

Example (a bit over-detailed. You can think of it as the first iteration in your loop):

z = (5 + 3i)
z^2 = (5 + 3i)^2
    = (5^2 + 3^2*i^2 + 2*5*3i)
    = (25 + 9i^2 + 30i)
    = (25 + 9*-1 + 30i)
    = (25 - 9 + 30i)
    = (16 + 30i)

Now if you understand the iteration and the multiplication of complex numbers, some words on Mandelbrot (and on the c value):

When you want to create a Mandelbrot set, you are really looking for points on the complex plane, that never goes to infinity if iterated over - say 50 times - with the iteration discussed above. The Mandelbrot set is the black part of the usually seen "Mandelbrot" pictures and not the shiny, colored part.

The usual workflow is this:

  • choose a point on the complex plane, say (1.01312 + 0.8324i) => this will be value of c !
  • before the first iteration put c's value into z then iterate over a number of times as stated before => z = z^2 + c. Yes, you are squaring a point and adding that same point to it. For a starter do this 50 times. This will give you a complex number as result
  • if any part of the resulting complex number (either the Real, or the Imaginary) is larger than 2, then that point went to infinity and that point is not part of the Mandelbrot set*. This is the case when you need to color the point (this is the colorful part of the Mandelbrot set). If the point did not go to infinity, then it is part of the set, and its color will be black
  • repeat (choose the next point and calculate)

*actually, verifying if a point is part of the set is a bit more complicated, but this works well for prototypes

share|improve this answer
1  
Hey thanks for taking your time to answer this one although it's about a month old. I already understood the basic scheme behind iterations but I'm still having trouble realising complex numbers as what they are (if that makes any sense). Anyways I gave up for now, but I'm sure I'll get back to that in a few months. –  Elias Schütt Mar 30 '12 at 16:14
1  
Mandelbrot set is boring after some time, the next step is Julia sets :-) –  karatedog Mar 30 '12 at 21:17
    
Heh, two years later I finally understood complex numbers. :D shadertoy.com/view/MsXXWN –  Elias Schütt May 26 at 18:00
    
@EliasSchütt Nice, congratulations :-) –  karatedog May 27 at 9:40

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