Fractal flame

Fractal flames are a member of the iterated function system class^[1] of fractals created by Scott Draves in 1992.^[2] Draves' open-source code was later ported into Adobe After Effects graphics software^[3] and translated into the Apophysis fractal flame editor.^[2]

Fractal flames differ from ordinary iterated function systems in three ways:

Nonlinear functions are iterated in addition to affine transforms.
Log-density display instead of linear or binary (a form of tone mapping)
Color by structure (i.e. by the recursive path taken) instead of monochrome or by density.

The tone mapping and coloring are designed to display as much of the detail of the fractal as possible, which generally results in a more aesthetically pleasing image.

Algorithm[edit]

The algorithm consists of two steps: creating a histogram and then rendering the histogram.

Creating the histogram[edit]

First, one iterates a set of functions, starting from a randomly chosen point P = (P.x,P.y,P.c), where the third coordinate indicates the current color of the point.

Set of flame functions:

{\begin{cases}F_{1}(x,y),\quad p_{1}\\F_{2}(x,y),\quad p_{2}\\\dots \\F_{n}(x,y),\quad p_{n}\end{cases}}

In each iteration, choose one of the functions above where the probability that F_j is chosen is p_j. Then one computes the next iteration of P by applying F_j on (P.x,P.y).

Each individual function has the following form:

F_{j}(x,y)=\sum _{V_{k}\in Variations}w_{k}\cdot V_{k}(a_{j}x+b_{j}y+c_{j},d_{j}x+e_{j}y+f_{j})

where the parameter w_k is called the weight of the variation V_k. Draves suggests ^[4] that all $w_{k}$ :s are non-negative and sum to one, but implementations such as Apophysis do not impose that restriction.

The functions V_k are a set of predefined functions. A few examples^[4] are

V₀(x,y) = (x,y) (Linear)
V₁(x,y) = (sin x,sin y) (Sinusoidal)
V₂(x,y) = (x,y)/(x²+y²) (Spherical)

The color P.c of the point is blended with the color associated with the latest applied function F_j:

P.c := (P.c + (F_j)_color) / 2

After each iteration, one updates the histogram at the point corresponding to (P.x,P.y). This is done as follows:

histogram[x][y][FREQUENCY] := histogram[x][y][FREQUENCY]+1
histogram[x][y][COLOR] := (histogram[x][y][COLOR] + P.c)/2

The colors in the image will therefore reflect what functions were used to get to that part of the image.

Rendering an image[edit]

To increase the quality of the image, one can use supersampling to decrease the noise. This involves creating a histogram larger than the image so each pixel has multiple data points to pull from. For example, create a histogram with 300×300 cells in order to draw a 100×100 px image; each pixel would use a 3×3 group of histogram buckets to calculate its value.

For each pixel (x,y) in the final image, do the following computations:

frequency_avg[x][y]  := average_of_histogram_cells_frequency(x,y);
color_avg[x][y] := average_of_histogram_cells_color(x,y);

alpha[x][y] := log(frequency_avg[x][y]) / log(frequency_max);  
//frequency_max is the maximal number of iterations that hit a cell in the histogram.

final_pixel_color[x][y] := color_avg[x][y] * alpha[x][y]^(1/gamma); //gamma is a value greater than 1.

The algorithm above uses gamma correction to make the colors appear brighter. This is implemented in for example the Apophysis software.

To increase the quality even more, one can use gamma correction on each individual color channel, but this is a very heavy computation, since the log function is slow.

A simplified algorithm would be to let the brightness be linearly dependent on the frequency:

final_pixel_color[x][y] := color_avg[x][y] * frequency_avg[x][y]/frequency_max;

but this would make some parts of the fractal lose detail, which is undesirable.^[4]

Density Estimation[edit]

The flame algorithm is like a Monte Carlo simulation, with the flame quality directly proportional to the number of iterations of the simulation. The noise that results from this stochastic sampling can be reduced by blurring the image, to get a smoother result in less time. One does not however want to lose resolution in the parts of the image that receive many samples and so have little noise.

This problem can be solved with adaptive density estimation to increase image quality while keeping render times to a minimum. FLAM3 uses a simplification of the methods presented in *Adaptive Filtering for Progressive Monte Carlo Image Rendering*, a paper presented at WSCG 2000 by Frank Suykens and Yves D. Willems. The idea is to vary the width of the filter inversely proportional to the number of samples available.

As a result, areas with few samples and high noise become blurred and smoothed, but areas with many samples and low noise are left unaffected.^[5]

Not all Flame implementations use density estimation.

References[edit]

^ Mitchell Whitelaw (2004). Metacreation: Art and Artificial Life. MIT Press. pp 155.
^ ^a ^b "Information about Apophysis software". Archived from the original on 2008-09-13. Retrieved 2008-03-11.
^ Chris Gehman and Steve Reinke (2005). The Sharpest Point: Animation at the End of Cinema. YYZ Books. pp 269.
^ ^a ^b ^c "The Fractal Flame Algorithm" (PDF). (22.5 MB)
^ See https://github.com/scottdraves/flam3/wiki/Density-Estimation.

[1] Mitchell Whitelaw (2004). Metacreation: Art and Artificial Life. MIT Press. pp 155.

[apophysis-2] "Information about Apophysis software". Archived from the original on 2008-09-13. Retrieved 2008-03-11.

[3] Chris Gehman and Steve Reinke (2005). The Sharpest Point: Animation at the End of Cinema. YYZ Books. pp 269.

[dravespdf-4] "The Fractal Flame Algorithm" (PDF). (22.5 MB)

[5] See https://github.com/scottdraves/flam3/wiki/Density-Estimation.

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[2]

[3]

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[5]

v t e Fractals
Characteristics	Fractal dimensions Assouad Box-counting Higuchi Correlation Hausdorff Packing Topological Recursion Self-similarity
Iterated function system	Barnsley fern Cantor set Koch snowflake Menger sponge Sierpinski carpet Sierpinski triangle Apollonian gasket Fibonacci word Space-filling curve Blancmange curve De Rham curve Minkowski Dragon curve Hilbert curve Koch curve Lévy C curve Moore curve Peano curve Sierpiński curve Z-order curve String T-square n-flake Vicsek fractal Hexaflake Gosper curve Pythagoras tree Weierstrass function
Strange attractor	Multifractal system
L-system	Fractal canopy Space-filling curve H tree
Escape-time fractals	Burning Ship fractal Julia set Filled Newton fractal Douady rabbit Lyapunov fractal Mandelbrot set Misiurewicz point Multibrot set Newton fractal Tricorn Mandelbox Mandelbulb
Rendering techniques	Buddhabrot Orbit trap Pickover stalk
Random fractals	Brownian motion Brownian tree Brownian motor Fractal landscape Lévy flight Percolation theory Self-avoiding walk
People	Michael Barnsley Georg Cantor Bill Gosper Felix Hausdorff Desmond Paul Henry Gaston Julia Helge von Koch Paul Lévy Aleksandr Lyapunov Benoit Mandelbrot Hamid Naderi Yeganeh Lewis Fry Richardson Wacław Sierpiński
Other	"How Long Is the Coast of Britain?" Coastline paradox Fractal art List of fractals by Hausdorff dimension The Fractal Geometry of Nature (1982 book) The Beauty of Fractals (1986 book) Chaos: Making a New Science (1987 book) Kaleidoscope Chaos theory

Algorithm[edit]

Creating the histogram[edit]

Rendering an image[edit]

Density Estimation[edit]

See also[edit]

References[edit]