Mandelbulb

The Mandelbulb is a three-dimensional fractal, constructed for the first time in 1997 by Jules Ruis and in 2009 further developed by Daniel White and Paul Nylander using spherical coordinates.

A 4K UHD 3D Mandelbulb video

A canonical 3-dimensional Mandelbrot set does not exist, since there is no 3-dimensional analogue of the 2-dimensional space of complex numbers. It is possible to construct Mandelbrot sets in 4 dimensions using quaternions and bicomplex numbers.

White and Nylander's formula for the "nth power" of the vector $\mathbf {v} =\langle x,y,z\rangle$ in $ℝ 3$ is

\mathbf {v} ^{n}:=r^{n}\langle \sin(n\theta )\cos(n\phi ),\sin(n\theta )\sin(n\phi ),\cos(n\theta )\rangle ,

where

r={\sqrt {x^{2}+y^{2}+z^{2}}},

\phi =\arctan {\frac {y}{x}}=\arg(x+yi),

\theta =\arctan {\frac {\sqrt {x^{2}+y^{2}}}{z}}=\arccos {\frac {z}{r}}.

The Mandelbulb is then defined as the set of those $\mathbf {c}$ in $ℝ 3$ for which the orbit of $\langle 0,0,0\rangle$ under the iteration $\mathbf {v} \mapsto \mathbf {v} ^{n}+\mathbf {c}$ is bounded.^[1] For n > 3, the result is a 3-dimensional bulb-like structure with fractal surface detail and a number of "lobes" depending on n. Many of their graphic renderings use n = 8. However, the equations can be simplified into rational polynomials when n is odd. For example, in the case n = 3, the third power can be simplified into the more elegant form:

\langle x,y,z\rangle ^{3}=\left\langle {\frac {(3z^{2}-x^{2}-y^{2})x(x^{2}-3y^{2})}{x^{2}+y^{2}}},{\frac {(3z^{2}-x^{2}-y^{2})y(3x^{2}-y^{2})}{x^{2}+y^{2}}},z(z^{2}-3x^{2}-3y^{2})\right\rangle .

The Mandelbulb given by the formula above is actually one in a family of fractals given by parameters (p, q) given by

\mathbf {v} ^{n}:=r^{n}\langle \sin(p\theta )\cos(q\phi ),\sin(p\theta )\sin(q\phi ),\cos(p\theta )\rangle .

Since p and q do not necessarily have to equal n for the identity |vⁿ| = |v|ⁿ to hold, more general fractals can be found by setting

\mathbf {v} ^{n}:=r^{n}{\big \langle }\sin {\big (}f(\theta ,\phi ){\big )}\cos {\big (}g(\theta ,\phi ){\big )},\sin {\big (}f(\theta ,\phi ){\big )}\sin {\big (}g(\theta ,\phi ){\big )},\cos {\big (}f(\theta ,\phi ){\big )}{\big \rangle }

for functions f and g.

Cubic formula edit

Cubic fractal

Other formulae come from identities parametrising the sum of squares to give a power of the sum of squares, such as

(x^{3}-3xy^{2}-3xz^{2})^{2}+(y^{3}-3yx^{2}+yz^{2})^{2}+(z^{3}-3zx^{2}+zy^{2})^{2}=(x^{2}+y^{2}+z^{2})^{3},

which we can think of as a way to cube a triplet of numbers so that the modulus is cubed. So this gives, for example,

x\to x^{3}-3x(y^{2}+z^{2})+x_{0}

y\to -y^{3}+3yx^{2}-yz^{2}+y_{0}

z\to z^{3}-3zx^{2}+zy^{2}+z_{0}

or other permutations.

This reduces to the complex fractal $w\to w^{3}+w_{0}$ when z = 0 and $w\to {\overline {w}}^{3}+w_{0}$ when y = 0.

There are several ways to combine two such "cubic" transforms to get a power-9 transform, which has slightly more structure.

Quintic formula edit

Quintic Mandelbulb

Quintic Mandelbulb with C = 2

Another way to create Mandelbulbs with cubic symmetry is by taking the complex iteration formula $z\to z^{4m+1}+z_{0}$ for some integer m and adding terms to make it symmetrical in 3 dimensions but keeping the cross-sections to be the same 2-dimensional fractal. (The 4 comes from the fact that $i^{4}=1$ .) For example, take the case of $z\to z^{5}+z_{0}$ . In two dimensions, where $z=x+iy$ , this is

x\to x^{5}-10x^{3}y^{2}+5xy^{4}+x_{0},

y\to y^{5}-10y^{3}x^{2}+5yx^{4}+y_{0}.

This can be then extended to three dimensions to give

x\to x^{5}-10x^{3}(y^{2}+Ayz+z^{2})+5x(y^{4}+By^{3}z+Cy^{2}z^{2}+Byz^{3}+z^{4})+Dx^{2}yz(y+z)+x_{0},

y\to y^{5}-10y^{3}(z^{2}+Axz+x^{2})+5y(z^{4}+Bz^{3}x+Cz^{2}x^{2}+Bzx^{3}+x^{4})+Dy^{2}zx(z+x)+y_{0},

z\to z^{5}-10z^{3}(x^{2}+Axy+y^{2})+5z(x^{4}+Bx^{3}y+Cx^{2}y^{2}+Bxy^{3}+y^{4})+Dz^{2}xy(x+y)+z_{0}

for arbitrary constants A, B, C and D, which give different Mandelbulbs (usually set to 0). The case $z\to z^{9}$ gives a Mandelbulb most similar to the first example, where n = 9. A more pleasing result for the fifth power is obtained by basing it on the formula $z\to -z^{5}+z_{0}$ .

Fractal based on z → −z⁵

Power-nine formula edit

Fractal with z⁹ Mandelbrot cross-sections

This fractal has cross-sections of the power-9 Mandelbrot fractal. It has 32 small bulbs sprouting from the main sphere. It is defined by, for example,

x\to x^{9}-36x^{7}(y^{2}+z^{2})+126x^{5}(y^{2}+z^{2})^{2}-84x^{3}(y^{2}+z^{2})^{3}+9x(y^{2}+z^{2})^{4}+x_{0},

y\to y^{9}-36y^{7}(z^{2}+x^{2})+126y^{5}(z^{2}+x^{2})^{2}-84y^{3}(z^{2}+x^{2})^{3}+9y(z^{2}+x^{2})^{4}+y_{0},

z\to z^{9}-36z^{7}(x^{2}+y^{2})+126z^{5}(x^{2}+y^{2})^{2}-84z^{3}(x^{2}+y^{2})^{3}+9z(x^{2}+y^{2})^{4}+z_{0}.

These formula can be written in a shorter way:

x\to {\frac {1}{2}}\left(x+i{\sqrt {y^{2}+z^{2}}}\right)^{9}+{\frac {1}{2}}\left(x-i{\sqrt {y^{2}+z^{2}}}\right)^{9}+x_{0}

and equivalently for the other coordinates.

Power-nine fractal detail

Spherical formula edit

A perfect spherical formula can be defined as a formula

(x,y,z)\to {\big (}f(x,y,z)+x_{0},g(x,y,z)+y_{0},h(x,y,z)+z_{0}{\big )},

where

(x^{2}+y^{2}+z^{2})^{n}=f(x,y,z)^{2}+g(x,y,z)^{2}+h(x,y,z)^{2},

where f, g and h are nth-power rational trinomials and n is an integer. The cubic fractal above is an example.

Uses in media edit

In the 2014 animated film Big Hero 6, the climax takes place in the middle of a wormhole, which is represented by the stylized interior of a Mandelbulb.^[2]^[3]
In the 2018 science fiction horror film Annihilation, an extraterrestrial being appears in the form of a partial Mandelbulb.^[4]
In the webcomic Unsounded the spirit realm of the khert is represented by a stylized golden mandelbulb.

References edit

^ "Mandelbulb: The Unravelling of the Real 3D Mandelbrot Fractal". see "formula" section.
^ Desowitz, Bill (January 30, 2015). "Immersed in Movies: Going Into the 'Big Hero 6' Portal". Animation Scoop. Indiewire. Archived from the original on May 3, 2015. Retrieved May 3, 2015.
^ Hutchins, David; Riley, Olun; Erickson, Jesse; Stomakhin, Alexey; Habel, Ralf; Kaschalk, Michael (2015). "Big Hero 6: Into the portal". ACM SIGGRAPH 2015 Talks. SIGGRAPH '15. New York, NY, USA: ACM. pp. 52:1. doi:10.1145/2775280.2792521. ISBN 9781450336369. S2CID 7488766.
^ Gaudette, Emily (February 26, 2018). "What Is Area X and the Shimmer in 'Annihilation'? VFX Supervisor Explains the Horror Film's Mathematical Solution". Newsweek. Retrieved March 9, 2018.

6. http://www.fractal.org the Fractal Navigator by Jules Ruis

External links edit

[1] "Mandelbulb: The Unravelling of the Real 3D Mandelbrot Fractal". see "formula" section.

[2] Desowitz, Bill (January 30, 2015). "Immersed in Movies: Going Into the 'Big Hero 6' Portal". Animation Scoop. Indiewire. Archived from the original on May 3, 2015. Retrieved May 3, 2015.

[3] Hutchins, David; Riley, Olun; Erickson, Jesse; Stomakhin, Alexey; Habel, Ralf; Kaschalk, Michael (2015). "Big Hero 6: Into the portal". ACM SIGGRAPH 2015 Talks. SIGGRAPH '15. New York, NY, USA: ACM. pp. 52:1. doi:10.1145/2775280.2792521. ISBN 9781450336369. S2CID 7488766.

[4] Gaudette, Emily (February 26, 2018). "What Is Area X and the Shimmer in 'Annihilation'? VFX Supervisor Explains the Horror Film's Mathematical Solution". Newsweek. Retrieved March 9, 2018.

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