Sierpiński carpet

6 steps of a Sierpinski carpet.

The Sierpiński carpet is a plane fractal first described by Wacław Sierpiński in 1916. The carpet is a generalization of the Cantor set to two dimensions; another is Cantor dust.

The technique of subdividing a shape into smaller copies of itself, removing one or more copies, and continuing recursively can be extended to other shapes. For instance, subdividing an equilateral triangle into four equilateral triangles, removing the middle triangle, and recursing leads to the Sierpiński triangle. In three dimensions, a similar construction based on cubes is known as the Menger sponge.

Construction[]

The construction of the Sierpiński carpet begins with a square. The square is cut into 9 congruent subsquares in a 3-by-3 grid, and the central subsquare is removed. The same procedure is then applied recursively to the remaining 8 subsquares, ad infinitum. It can be realised as the set of points in the unit square whose coordinates written in base three do not both have a digit '1' in the same position, using the infinitesimal number representation of $0.1111\dots =0.2$ .^[1]

The process of recursively removing squares is an example of a finite subdivision rule.

Properties[]

Variant of the Peano curve with the middle line erased creates a Sierpiński carpet

The area of the carpet is zero (in standard Lebesgue measure).

Proof: Denote as

a i

the area of iteration

i

. Then

ai + 1 = .mw-parser-output .sfrac{white-space:nowrap}.mw-parser-output .sfrac.tion,.mw-parser-output .sfrac .tion{display:inline-block;vertical-align:-0.5em;font-size:85%;text-align:center}.mw-parser-output .sfrac .num,.mw-parser-output .sfrac .den{display:block;line-height:1em;margin:0 0.1em}.mw-parser-output .sfrac .den{border-top:1px solid}.mw-parser-output .sr-only{border:0;clip:rect(0,0,0,0);height:1px;margin:-1px;overflow:hidden;padding:0;position:absolute;width:1px}8/9ai

. So

a i = (8 / 9) i

, which tends to 0 as

i

goes to infinity.

The interior of the carpet is empty.

Proof: Suppose by contradiction that there is a point

P

in the interior of the carpet. Then there is a square centered at

P

which is entirely contained in the carpet. This square contains a smaller square whose coordinates are multiples of

1 / 3 k

for some

k

. But, this square must have been holed in iteration

k

, so it cannot be contained in the carpet – a contradiction.

The Hausdorff dimension of the carpet is $log 8 / log 3 \approx 1.8928$ .^[2]

Sierpiński demonstrated that his carpet is a universal plane curve.^[3] That is: the Sierpinski carpet is a compact subset of the plane with Lebesgue covering dimension 1, and every subset of the plane with these properties is homeomorphic to some subset of the Sierpiński carpet.

This 'universality' of the Sierpiński carpet is not a true universal property in the sense of category theory: it does not uniquely characterize this space up to homeomorphism. For example, the disjoint union of a Sierpiński carpet and a circle is also a universal plane curve. However, in 1958 Gordon Whyburn^[4] uniquely characterized the Sierpiński carpet as follows: any curve that is locally connected and has no 'local cut-points' is homeomorphic to the Sierpinski carpet. Here a local cut-point is a point $p$ for which some connected neighborhood $U$ of $p$ has the property that $U - {p}$ is not connected. So, for example, any point of the circle is a local cut point.

In the same paper Whyburn gave another characterization of the Sierpiński carpet. Recall that a continuum is a nonempty connected compact metric space. Suppose $X$ is a continuum embedded in the plane. Suppose its complement in the plane has countably many connected components $C 1, C 2, C 3, ...$ and suppose:

the diameter of $C i$ goes to zero as $i \to \infty$ ;
the boundary of $C i$ and the boundary of $C j$ are disjoint if $i \neq j$ ;
the boundary of $C i$ is a simple closed curve for each $i$ ;
the union of the boundaries of the sets $C i$ is dense in $X$ .

Then $X$ is homeomorphic to the Sierpiński carpet.

Brownian motion on the Sierpiński carpet[]

The topic of Brownian motion on the Sierpiński carpet has attracted interest in recent years.^[5] Martin Barlow and Richard Bass have shown that a random walk on the Sierpiński carpet diffuses at a slower rate than an unrestricted random walk in the plane. The latter reaches a mean distance proportional to $\sqrt n$ after $n$ steps, but the random walk on the discrete Sierpiński carpet reaches only a mean distance proportional to $β \sqrt n$ for some $β > 2$ . They also showed that this random walk satisfies stronger large deviation inequalities (so called "sub-Gaussian inequalities") and that it satisfies the elliptic Harnack inequality without satisfying the parabolic one. The existence of such an example was an open problem for many years.

Wallis sieve[]

Third iteration of the Wallis sieve

A variation of the Sierpiński carpet, called the Wallis sieve, starts in the same way, by subdividing the unit square into nine smaller squares and removing the middle of them. At the next level of subdivision, it subdivides each of the squares into 25 smaller squares and removes the middle one, and it continues at the $i$ th step by subdividing each square into $(2 i + 1) 2$ (the odd squares^[6]) smaller squares and removing the middle one.

By the Wallis product, the area of the resulting set is $π$ /4,^[7]^[8] unlike the standard Sierpiński carpet which has zero limiting area.

However, by the results of Whyburn mentioned above, we can see that the Wallis sieve is homeomorphic to the Sierpiński carpet. In particular, its interior is still empty.

Applications[]

Mobile phone and WiFi fractal antennas have been produced in the form of few iterations of the Sierpiński carpet. Due to their self-similarity and scale invariance, they easily accommodate multiple frequencies. They are also easy to fabricate and smaller than conventional antennas of similar performance, thus being optimal for pocket-sized mobile phones.

References[]

^ Allouche, Jean-Paul; Shallit, Jeffrey (2003). Automatic Sequences: Theory, Applications, Generalizations. Cambridge University Press. pp. 405–406. ISBN 978-0-521-82332-6. Zbl 1086.11015.
^ Semmes, Stephen (2001). Some Novel Types of Fractal Geometry. Oxford Mathematical Monographs. Oxford University Press. p. 31. ISBN 0-19-850806-9. Zbl 0970.28001.
^ Sierpiński, Wacław (1916). "Sur une courbe cantorienne qui contient une image biunivoque et continue de toute courbe donnée". C. R. Acad. Sci. Paris (in French). 162: 629–632. ISSN 0001-4036. JFM 46.0295.02.
^ Whyburn, Gordon (1958). "Topological chcracterization of the Sierpinski curve". Fund. Math. 45: 320–324. doi:10.4064/fm-45-1-320-324.
^ Barlow, Martin; Bass, Richard, Brownian motion and harmonic analysis on Sierpiński carpets (PDF)
^ Sloane, N. J. A. (ed.). "Sequence A016754 (Odd squares: a(n) = (2n+1)^2. Also centered octagonal numbers.)". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation.
^ Rummler, Hansklaus (1993). "Squaring the circle with holes". The American Mathematical Monthly. 100 (9): 858–860. doi:10.2307/2324662. JSTOR 2324662. MR 1247533.
^ Weisstein, Eric W. "Wallis Sieve". MathWorld.

External links[]

[1] Allouche, Jean-Paul; Shallit, Jeffrey (2003). Automatic Sequences: Theory, Applications, Generalizations. Cambridge University Press. pp. 405–406. ISBN 978-0-521-82332-6. Zbl 1086.11015.

[2] Semmes, Stephen (2001). Some Novel Types of Fractal Geometry. Oxford Mathematical Monographs. Oxford University Press. p. 31. ISBN 0-19-850806-9. Zbl 0970.28001.

[sierpinski-3] Sierpiński, Wacław (1916). "Sur une courbe cantorienne qui contient une image biunivoque et continue de toute courbe donnée". C. R. Acad. Sci. Paris (in French). 162: 629–632. ISSN 0001-4036. JFM 46.0295.02.

[whyburn-4] Whyburn, Gordon (1958). "Topological chcracterization of the Sierpinski curve". Fund. Math. 45: 320–324. doi:10.4064/fm-45-1-320-324.

[barlow-5] Barlow, Martin; Bass, Richard, Brownian motion and harmonic analysis on Sierpiński carpets (PDF)

[6] Sloane, N. J. A. (ed.). "Sequence A016754 (Odd squares: a(n) = (2n+1)^2. Also centered octagonal numbers.)". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation.

[7] Rummler, Hansklaus (1993). "Squaring the circle with holes". The American Mathematical Monthly. 100 (9): 858–860. doi:10.2307/2324662. JSTOR 2324662. MR 1247533.

[8] Weisstein, Eric W. "Wallis Sieve". MathWorld.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

hide 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 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