Assouad dimension

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The Assouad dimension of the Sierpiński triangle is equal to its Hausdorff dimension, [math]\displaystyle{ \alpha = \frac{\log(3)}{\log(2)} }[/math]. In the illustration, we see that for a particular choice of r, R, and x, [math]\displaystyle{ N_{r}(B_{R}(x) \cap E) = 3 = 2^\alpha = \left( \frac{R}{r} \right)^{\alpha}. }[/math] For other choices, the constant C may be greater than 1, but is still bounded.

In mathematics — specifically, in fractal geometry — the Assouad dimension is a definition of fractal dimension for subsets of a metric space. It was introduced by Patrice Assouad in his 1977 PhD thesis and later published in 1979,[1] although the same notion had been studied in 1928 by Georges Bouligand.[2] As well as being used to study fractals, the Assouad dimension has also been used to study quasiconformal mappings and embeddability problems.

Definition

The Assouad dimension of [math]\displaystyle{ X, d_A(X) }[/math], is the infimum of all [math]\displaystyle{ s }[/math] such that [math]\displaystyle{ (X, \varsigma) }[/math] is [math]\displaystyle{ (M, s) }[/math]-homogeneous for some [math]\displaystyle{ M \ge 1 }[/math].[3]

Let [math]\displaystyle{ (X, d) }[/math] be a metric space, and let E be a non-empty subset of X. For r > 0, let [math]\displaystyle{ N_{r}(E) }[/math] denote the least number of metric open balls of radius less than or equal to r with which it is possible to cover the set E. The Assouad dimension of E is defined to be the infimal [math]\displaystyle{ \alpha \ge 0 }[/math] for which there exist positive constants C and [math]\displaystyle{ \rho }[/math] so that, whenever [math]\displaystyle{ 0 \lt r \lt R \leq \rho, }[/math] the following bound holds: [math]\displaystyle{ \sup_{x \in E} N_{r}(B_{R}(x) \cap E) \leq C \left( \frac{R}{r} \right)^{\alpha}. }[/math]

The intuition underlying this definition is that, for a set E with "ordinary" integer dimension n, the number of small balls of radius r needed to cover the intersection of a larger ball of radius R with E will scale like (R/r)n.

Relationships to other notions of dimension

  • The Assouad dimension of a metric space is always greater than or equal to its Assouad–Nagata dimension.[4]
  • The Assouad dimension of a metric space is always greater than or equal to its upper box dimension, which in turn is greater than or equal to the Hausdorff dimension.[5]
  • The Lebesgue covering dimension of a metrizable space X is the minimal Assouad dimension of any metric on X. In particular, for every metrizable space there is a metric for which the Assouad dimension is equal to the Lebesgue covering dimension.[5]

References

  1. Assouad, Patrice (1979). "Étude d'une dimension métrique liée à la possibilité de plongements dans Rn" (in fr). Comptes Rendus de l'Académie des Sciences, Série A-B 288 (15): A731–A734. ISSN 0151-0509.  MR532401
  2. Bouligand, Georges (1928). "Ensembles impropres et nombre dimensionnel" (in fr). Bulletin des Sciences Mathématiques 52: 320–344. https://gallica.bnf.fr/ark:/12148/bpt6k486279t/f406.item. 
  3. Robinson, James C. (2010). Dimensions, Embeddings, and Attractors. Cambridge University Press. p. 85. ISBN 9781139495189. https://books.google.com/books?id=qFyXxiKfA9UC&dq=Assouad+dimension&pg=PA83. 
  4. Le Donne, Enrico; Rajala, Tapio (2015). "Assouad dimension, Nagata dimension, and uniformly close metric tangents". Indiana University Mathematics Journal 64 (1): 21–54. doi:10.1512/iumj.2015.64.5469. 
  5. 5.0 5.1 Luukkainen, Jouni (1998). "Assouad dimension: antifractal metrization, porous sets, and homogeneous measures". Journal of the Korean Mathematical Society 35 (1): 23–76. ISSN 0304-9914. https://koreascience.kr/article/JAKO199811919486026.page. 

Further reading



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