Vicsek fractal

Vicsek fractal (5th iteration of cross form)

In mathematics the Vicsek fractal, also known as Vicsek snowflake or box fractal,^[1]^[2] is a fractal arising from a construction similar to that of the Sierpinski carpet, proposed by Tamás Vicsek. It has applications including as compact antennas, particularly in cellular phones.

Variant^[3]

6 steps of a Sierpinski carpet

Self-affine fractal built from a

3 \times 2

grid

Box fractal also refers to various iterated fractals created by a square or rectangular grid with various boxes removed or absent and, at each iteration, those present and/or those absent have the previous image scaled down and drawn within them. The Sierpinski triangle may be approximated by a $2 \times 2$ box fractal with one corner removed. The Sierpinski carpet is a $3 \times 3$ box fractal with the middle square removed.

Construction[]

The basic square is decomposed into nine smaller squares in the 3-by-3 grid. The four squares at the corners and the middle square are left, the other squares being removed. The process is repeated recursively for each of the five remaining subsquares. The Vicsek fractal is the set obtained at the limit of this procedure. The Hausdorff dimension of this fractal is $\textstyle {\frac {\log(5)}{\log(3)}}$ ≈ 1.46497.

An alternative construction (shown below in the left image) is to remove the four corner squares and leave the middle square and the squares above, below, left and right of it. The two constructions produce identical limiting curves, but one is rotated by 45 degrees with respect to the other.

Self-similarities I — removing corner squares.
Self-similarities II — keeping corner squares.4

Four iterations of the saltire form of the fractal (top) and the cross form of the fractal (bottom).

Anticross-stitch curve, iterations 0-4

Cross-stitch island

Approximation by the chaos game where the jump=2/3 randomly towards either the center or one of the vertices of a square

Properties[]

The Vicsek fractal has the surprising property that it has zero area yet an infinite perimeter, due to its non-integer dimension. At each iteration, four squares are removed for every five retained, meaning that at iteration n the area is $\textstyle {({\frac {5}{9}})^{n}}$ (assuming an initial square of side length 1). When n approached infinity, the area approaches zero. The perimeter however is $\textstyle {4({\frac {5}{3}})^{n}}$ , because each side is divided into three parts and the center one is replaced with three sides, yielding an increase of three to five. The perimeter approaches infinity as n increases.

The boundary of the Vicsek fractal is the Type 1 quadratic Koch curve.

Analogues in higher dimensions[]

Animation of the 3D analogue of the Vicsek fractal (third iteration)

Play media

Flight to and around a 3D Vicsek fractal

There is a three-dimensional analogue of the Vicsek fractal. It is constructed by subdividing each cube into 27 smaller ones, and removing all but the "center cross", the central cube and the six cubes touching the center of each face. Its Hausdorff dimension is $\textstyle {\frac {\log(7)}{\log(3)}}$ ≈ 1.7712.

Similarly to the two-dimensional Vicsek fractal, this figure has zero volume. Each iteration retains 7 cubes for every 27, resulting in a volume of $\textstyle {({\frac {7}{27}})^{n}}$ at iteration n, which approaches zero as n approaches infinity.

There exist an infinite number of cross sections which yield the two-dimensional Vicsek fractal.

References[]

^ Shan Fuqi; Gu Hongming; Gao Baoxin (2004). "Analysis of a vicsek fractal patch antenna". ICMMT 4th International Conference On, Proceedings Microwave and Millimeter Wave Technology, 2004. Beijing, China: IEEE: 98–101. doi:10.1109/ICMMT.2004.1411469. ISBN 9780780384019.
^ Weisstein, Eric W. "Box Fractal". MathWorld.
^ "Box Fractals". 2014-01-03.

External links[]

"Box Fractal". Wolfram Alpha Site. Retrieved 21 February 2019.

[1] Shan Fuqi; Gu Hongming; Gao Baoxin (2004). "Analysis of a vicsek fractal patch antenna". ICMMT 4th International Conference On, Proceedings Microwave and Millimeter Wave Technology, 2004. Beijing, China: IEEE: 98–101. doi:10.1109/ICMMT.2004.1411469. ISBN 9780780384019.

[2] Weisstein, Eric W. "Box Fractal". MathWorld.

[3] "Box Fractals". 2014-01-03.

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v t Fractals
Characteristics	Fractal dimensions Assouad Box-counting 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 T-square n-flake Vicsek fractal Hexaflake Gosper curve Pythagoras tree
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 List of fractals by Hausdorff dimension The Beauty of Fractals (1986 book) Fractal art Chaos: Making a New Science (1987 book) The Fractal Geometry of Nature (1982 book) Kaleidoscope Chaos theory