Assouad–Nagata dimension

In mathematics, the Assouad–Nagata dimension (sometimes simply Nagata dimension) is a notion of dimension for metric spaces,^[1]^[2] introduced by Jun-iti Nagata in 1958^[3] and reformulated by Patrice Assouad in 1982, who introduced the now-usual definition.^[4]

Definition edit

The Assouad–Nagata dimension of a metric space $(X, d)$ is defined as the smallest integer $n$ for which there exists a constant $C > 0$ such that for all $r > 0$ the space $X$ has a $Cr$ -bounded covering with $r$ -multiplicity at most $n + 1$ . Here $Cr$ -bounded means that the diameter of each set of the covering is bounded by $Cr$ , and $r$ -multiplicity is the infimum of integers $k \geq 0$ such that each subset of $X$ with diameter at most $r$ has a non-empty intersection with at most $k$ members of the covering.

This definition can be rephrased to make it more similar to that of the Lebesgue covering dimension. The Assouad–Nagata dimension of a metric space $(X, d)$ is the smallest integer $n$ for which there exists a constant $c > 0$ such that for every $r > 0$ , the covering of $X$ by $r$ -balls has a refinement with $cr$ -multiplicity at most $n + 1$ .

Relationship to other notions of dimension edit

Compare the similar definitions of Lebesgue covering dimension and asymptotic dimension. A space has Lebesgue covering dimension at most $n$ if it is at most $n$ -dimensional at microscopic scales, and asymptotic dimension at most $n$ if it looks at most $n$ -dimensional upon zooming out as far as you need. To have Assouad–Nagata dimension at most $n$ , a space has to look at most $n$ -dimensional at every possible scale, in a uniform way across scales.

The Nagata dimension of a metric space is always less than or equal to its Assouad dimension.^[5]

References edit

^ Cobzaş, Ş.; Miculescu, R.; Nicolae, A. (2019). Lipschitz functions. Cham, Switzerland: Springer. p. 308. ISBN 978-3-030-16488-1.
^ Lang, Urs; Schlichenmaier, Thilo (2005). "Nagata dimension, quasisymmetric embeddings, and Lipschitz extensions". International Mathematics Research Notices. 2005 (58): 3625. arXiv:math/0410048. doi:10.1155/IMRN.2005.3625. S2CID 119683379.{{cite journal}}: CS1 maint: unflagged free DOI (link)
^ Nagata, J. (1958). "Note on dimension theory for metric spaces". Fundamenta Mathematicae. 45: 143–181. doi:10.4064/fm-45-1-143-181.
^ Assouad, P. (January 4, 1982). "Sur la distance de Nagata". Comptes Rendus de l'Académie des Sciences, Série I (in French). 294 (1): 31–34.
^ Le Donne, Enrico; Rajala, Tapio (2015). "Assouad dimension, Nagata dimension, and uniformly close metric tangents". Indiana University Mathematics Journal. 64 (1): 21–54. arXiv:1306.5859. doi:10.1512/iumj.2015.64.5469. S2CID 55039643.

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[1] Cobzaş, Ş.; Miculescu, R.; Nicolae, A. (2019). Lipschitz functions. Cham, Switzerland: Springer. p. 308. ISBN 978-3-030-16488-1.

[2] Lang, Urs; Schlichenmaier, Thilo (2005). "Nagata dimension, quasisymmetric embeddings, and Lipschitz extensions". International Mathematics Research Notices. 2005 (58): 3625. arXiv:math/0410048. doi:10.1155/IMRN.2005.3625. S2CID 119683379.{{cite journal}}: CS1 maint: unflagged free DOI (link)

[3] Nagata, J. (1958). "Note on dimension theory for metric spaces". Fundamenta Mathematicae. 45: 143–181. doi:10.4064/fm-45-1-143-181.

[4] Assouad, P. (January 4, 1982). "Sur la distance de Nagata". Comptes Rendus de l'Académie des Sciences, Série I (in French). 294 (1): 31–34.

[5] Le Donne, Enrico; Rajala, Tapio (2015). "Assouad dimension, Nagata dimension, and uniformly close metric tangents". Indiana University Mathematics Journal. 64 (1): 21–54. arXiv:1306.5859. doi:10.1512/iumj.2015.64.5469. S2CID 55039643.

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