It has been suggested that this page's contents be merged with the page Recursion. You can discuss this on the page's talk page. (August 2016) |
Recursion is the process of repeating items in a self-similar way. Recursion can be implemented in Scratch by making a block that uses itself. This can be used to create fractals. A fractal is pattern that produces a picture, which contains an infinite amount of copies of itself. Some well-known specimens are the Mandelbrot set, the Sierpinski Triangle (also, but less commonly known as the Sierpinski Gasket), and the Koch Snowflake.
Creating the Koch Curve
The Koch Curve is a fractal that can be created relatively easily in Scratch. The Koch Curve is a piece of the larger fractal, the Koch Snowflake.
Understanding Recursion in the Koch Curve
The Koch Curve is made of four Koch Curves that are a third of the size of the original Koch Curve. They are they are arranged so that the first and fourth are flat and the middle two point up to make an equilateral that is triangle missing one side.
To make it easier to draw, the Koch Curve can be broken down into iterations, each one more complicated than the last. The first iteration is made up of four straight lines. The second iteration contains four copies of the first iteration. The third iteration contains four copies of the second iteration or sixteen copies of the first iteration. As iterations are added it gets more complicated and looks more and more like the real Koch Curve.
Implementation in Scratch
Basic Pen Path without Recursion
The triangle in the center is an equilateral triangle, therefore each of its angles have a measure of 60°.
Using basic geometry the angles of the rotations the sprite must make can be found.
Using this these angles, a script can be created that draws the first iteration of Koch Curve. Since each line segment is 1/3 the total length of the Koch Curve, the sprite should move 1/3 of the length given each time.
when gf clicked point in direction (90) //make sure the sprite is pointed right go to x: (-240) y: (-179) //put the sprite in the lower left corner clear //clear graphics from previous runs pen down //put the pen down for drawing make the first iteration of the Koch Curve with a length of (480) pen up //put the pen up so movement afterwards is not recorded define make the first iteration of the Koch Curve with a length of (length) move ((length) / (3)) steps //draw a line segment turn ccw (60) degrees //first turn move ((length) / (3)) steps //draw a line segment turn cw (120) degrees //second turn move ((length) / (3)) steps //draw a line segment turn ccw (60) degrees //third turn move ((length) / (3)) steps //draw a line segment
Adding Recursion
To add recursion, instead of drawing a line, a smaller Koch Curve can be drawn. When each iteration above one is drawn, it contains four smaller Koch Curves that are one iteration less than it self. For example, when drawing the second iteration you must draw four copies that are 1/3 the size of the first iteration. When the program gets to the first iteration it must draw straight lines. The following code will make the fifth iteration of the Koch Curve
when gf clicked point in direction (90) //make sure the sprite is pointed right go to x: (-240) y: (-179) //put the sprite in the lower left corner clear //clear graphics from previous runs pen down //put the pen down for drawing make the (5) iteration of the Koch Curve with a length of (480) pen up //put the pen up so movement afterwards is not recorded define make the (iteration) iteration of the Koch Curve with a length of (length) if <(iteration) = [1]> then //is it the first iteration? move ((length) / (3)) steps //draw a line segment else make the ((iteration) - (1)) iteration of the Koch Curve with a length of ((length) / (3)) //make a smaller Koch Curve end turn ccw (60) degrees //first turn if <(iteration) = [1]> then //is it the first iteration? move ((length) / (3)) steps //draw a line segment else make the ((iteration) - (1)) iteration of the Koch Curve with a length of ((length) / (3)) //make a smaller Koch Curve end turn cw (120) degrees //second turn if <(iteration) = [1]> then //is it the first iteration? move ((length) / (3)) steps //draw a line segment else make the ((iteration) - (1)) iteration of the Koch Curve with a length of ((length) / (3)) //make a smaller Koch Curve end turn ccw (60) degrees //third turn if <(iteration) = [1]> then //is it the first iteration? move ((length) / (3)) steps //draw a line segment else make the ((iteration) - (1)) iteration of the Koch Curve with a length of ((length) / (3)) //make a smaller Koch Curve end
Creating the Mandelbrot Set
The Mandelbrot set is a mathematical fractal defined in the complex plane. It is completely self-similar, meaning that it repeats over and over as one zooms in. The Mandelbrot set was named after its discoverer, Benoit Mandelbrot, and has many close relationships to the Julia Sets.
Understanding the Definition
In its definition, the Mandelbrot uses complex numbers. A complex number is the sum of a real number and an imaginary one, with an imaginary number simply being the square root of a negative number. Since that can not be taken, the square root of -1 is assigned the value i. For example, 3+3i is a complex number.
The Mandelbrot set is defined as all c values in the complex plain which are bounded under iteration in the following equation:
First, one starts with a z value of c (i.e. z_{1} = c). Then, when one puts that z back into the equation, it becomes z^2+c. That z is then taken and put back through the equation over and over. This is called iteration.
For example, let c=1. The value z then becomes 1. Once 1 is put back into the equation, the equation becomes 1^2+1, which equals 2. Once 2 is put back in, it becomes 2^2+1, or 5. Once 5 is put back in, it becomes 26. That sequence escapes to infinity and therefore c=1 is not part of the Mandelbrot set. Meanwhile, the sequence c=-1 gives 0, -1, 0, -1, 0, ect..., is bounded and so belongs to the Mandelbrot set.
It has been proven that if any sequence contains a complex value that is outside a distance of 2 from the origin, it will escape to infinity.
Coloring
In a basic Mandelbrot set, white is used for a c-values that escape to infinity and black is used for all c-values that do not. This would be the actual Mandelbrot set.
In most Mandelbrot sets, though, colors are used to help depict the Mandelbrot set or make it more art-orientated. Colors are not defined through an equation, but rather through the last iteration before escaping a distance of two from the origin. The iteration is then assigned a color of the creator's preference. Color can also apply to the rate of the equation reaching infinity.
Implementation in Scratch
Creating the Variables
Due to the fact that Scratch does not directly support mathematics in the complex plain, a simple workaround has to be used. Each complex number will be defined as two variables, the real part, and the complex part. And since there will be operations based on the complex numbers, two complex numbers will be needed, or four variables. For the tutorial, these names will be used:
- Real 1
- Real 2
- Complex 1
- Complex 2
Along with that, a variable Best Fit will be used to figure out the color to be used when coloring a complex value:
- Best Fit
Coding
To start, a base of clones is needed to render a full screen due to the computing power needed to render the Mandelbrot set:
when gf clicked hide//so that this sprite and its clones do not show set y to (180) clear//preparing the scene for the Mandelbrot set repeat (12) create clone of [myself v] change y by (-1)//this makes it so that clones do not overlap end
Next, it is important to give the clones a skeleton:
when I start as a clone set pen size to (1.5)//any other size will appear transparent set x to (-180)//the left hand side of the Mandelbrot set repeat ((360) / (12))//12 clones and each gets 30 rows on the screen to render repeat (360)//360 pixels will be the width of the Mandelbrot set once rendered //this is where we'll be rendering each point end change y by (-12)//the clone finished a row and moves to another set x to (-180) end
Although this is a functional script, it will take a while to render. For speed preferences, we'll be inserting a custom block:
when I start as a clone set pen size to (1.5) set x to (-180) repeat (30) repeat (60) forced iteration::custom//renders 6 points without a screen refresh for speed benefits end change y by (-12) set x to (-180) end define forced iteration //make sure this runs without screen refresh! repeat (6)//here is where we'll be rendering points now end
As noted above, it is important that the custom block "forced iteration" runs without a screen refresh or else all the benefit of extra speed will be lost.
Anyway, now that that is coded, we need to create the skeleton for sampling a point and figuring out whether or not it is part of the Mandelbrot set:
define forced iteration //make sure it runs without screen refresh repeat (6) set [Real 1 v] to ((x position) / (90))//90 pixels to the right is the equivalent of 1 set [Imaginary 1 v] to ((y position) / (90))//90 pixels upwards is the equivalent of i if <([sqrt v] of (((Real 1) * (Real 1)) + ((Imaginary 1) * (Imaginary 1)))) < (2.15)> then Test for Legibility at R: (Real 1) I: (Imaginary 1)::custom Set Pen Color::custom pen down//drawing the point pen up end change x by (1)//moving onto another point end define Test for Legibility at R: (Real) I: (Imaginary) //this is where we'll test if a point is part of the Mandelbrot set or not define Set Pen Color //this is where we pick our color depending on the variable 'Best Fit'
Now here is where the mathematics of the Mandelbrot set comes into play. In the Test for Legibility custom block, we'll have to take a complex number, apply the equation which defines the Mandelbrot set, and repeat if it is still within a distance of 2 from the origin:
define Test for Legibility at R: (Real) I: (Imaginary) set [Best Fit v] to (-1) repeat until <<(Best Fit) = (20)> or <([sqrt v] of (((Real 1) * (Real 1)) + ((Imaginary 1) * (Imaginary 1)))) > (2)>> change [Best Fit v] by (1)//the complex number has survived one iteration set [Real 2 v] to ((((Real 1) * (Real 1)) - ((Imaginary 1) * (Imaginary 1))) + (Real)) set [Imaginary 2 v] to (((2) * ((Real 1) * (Imaginary 1))) + (Imaginary)) set [Real 1 v] to (Real 2)//setting the scene for another iteration set [Imaginary 1 v] to (Imaginary 2) end
Up above, it may be noticed that the repeat continues until the complex number is found not to be part of the Mandelbrot set, or until it has iterated 20 times. That 20 can be changed to whatever one wants, with higher numbers producing higher quality; though the higher the number, the more lag will be caused.
To complete the Mandelbrot set, colors need to be implemented:
define Set Pen Color if <(Best Fit) = (-1)> then set pen color to [#000]//this point is already outside a distance of 2 from the origin else if <(Best Fit) = (20)> then set pen color to [#FFF]//this point is a solution to the Mandelbrot set else set pen color to (50)//this complex number is not a solution, but survives several iterations set pen shade to (((0) - (Best Fit)) * (5)) end end
Those colors may be changed to one's wishes.
Final Product
In the end, this is all the code used to draw the Mandelbrot set (scroll to see all of the code):
when gf clicked hide set y to (180) clear repeat (12) create clone of [myself v] change y by (-1)//this makes it so that clones do not overlap end when I start as a clone set pen size to (1.5) set x to (-180) repeat (30) repeat (60) forced iteration::custom end change y by (-12) set x to (-180) end define forced iteration //remember, run this without screen refresh! repeat (6) set [Real 1 v] to ((x position) / (90)) set [Imaginary 1 v] to ((y position) / (90)) if <([sqrt v] of (((Real 1) * (Real 1)) + ((Imaginary 1) * (Imaginary 1)))) < (2.15)> then Test for Legibility at R: (Real 1) I: (Imaginary 1) Set Pen Color pen down//drawing the point pen up end change x by (1)//moving onto another point end define Test for Legibility at R: (Real) I: (Imaginary) set [Best Fit v] to (-1) repeat until <<(Best Fit) = (20)> or <([sqrt v] of (((Real 1) * (Real 1)) + ((Imaginary 1) * (Imaginary 1)))) > (2)>> change [Best Fit v] by (1)//the complex number has survived one iteration set [Real 2 v] to ((((Real 1) * (Real 1)) - ((Imaginary 1) * (Imaginary 1))) + (Real)) set [Imaginary 2 v] to (((2) * ((Real 1) * (Imaginary 1))) + (Imaginary)) set [Real 1 v] to (Real 2) set [Imaginary 1 v] to (Imaginary 2) end define Set Pen Color if <(Best Fit) = (-1)> then set pen color to [#000]//this point is already outside a distance of 2 from the origin else if <(Best Fit) = (20)> then set pen color to [#FFF]//this point is a solution to the Mandelbrot set else set pen color to (50)//this complex number is not a solution, but survives several iterations set pen shade to (((0) - (Best Fit)) * (5)) end end
Julia Set
The Julia set is a series of equations that are mathematical fractals, and that is defined very similarly to the Mandelbrot set. The official equation is:
The only difference in its definition from the Mandelbrot set is that c is no longer a point in the complex plane, but rather a complex parameter, which is consistent whichever point you pick. Also, z1 is defined as being the point you pick in the complex plane. The technique above for rendering the Mandelbrot set may be used here again, with the required changes.
Here is a gallery of images on the Julia set: