Laakso space
In mathematical analysis and metric geometry, Laakso spaces[1][2] are a class of metric spaces which are fractal, in the sense that they have non-integer Hausdorff dimension, but that admit a notion of differential calculus. They are constructed as quotient spaces of [0, 1] × K where K is a Cantor set.[3]
Background[edit]
Cheeger defined a notion of differentiability for real-valued functions on metric measure spaces which are doubling and satisfy a Poincaré inequality, generalizing the usual notion on Euclidean space and Riemannian manifolds. Spaces that satisfy these conditions include Carnot groups and other sub-Riemannian manifolds, but not classic fractals such as the Koch snowflake or the Sierpiński gasket. The question therefore arose whether spaces of fractional Hausdorff dimension can satisfy a Poincaré inequality. Bourdon and Pajot[4] were the first to construct such spaces. Tomi J. Laakso[3] gave a different construction which gave spaces with Hausdorff dimension any real number greater than 1. These examples are now known as Laakso spaces.
Construction[edit]
We describe a space with Hausdorff dimension . (For integer dimensions, Euclidean spaces satisfy the desired condition, and for any Hausdorff dimension S + r in the interval (S, S + 1), where S is an integer, we can take the space .) Let t ∈ (0, 1/2) be such that
To save on notation, we now assume that t = 1/3, so that K is the usual middle thirds Cantor set. The general construction is similar but more complicated. Recall that the middle thirds Cantor set consists of all points in [0, 1] whose ternary expansion consists of only 0's and 2's. Given a string a of 0's and 2's, let Ka be the subset of points of K consisting of points whose ternary expansion starts with a. For example,
We give the resulting quotient space the quotient metric:
In the general case, the numbers b (called wormhole levels) and their orders k are defined in a more complicated way so as to obtain a space with the right Hausdorff dimension, but the basic idea is the same.
Properties[edit]
- FQ is a doubling space and satisfies a (1, 1)-Poincaré inequality.
- FQ does not have a bilipschitz embedding into any Euclidean space.
References[edit]
- ^ Heinonen, Juha; Koskela, Pekka; Shanmugalingam, Nageswari; Tyson, Jeremy T. (2015). Sobolev spaces on metric measure spaces: an approach based on upper gradients. Cambridge University Press. p. 403. ISBN 9781107092341.
- ^ Heinonen, Juha (24 January 2007). "Nonsmooth calculus". Bulletin of the American Mathematical Society. 44 (2): 163–232. doi:10.1090/S0273-0979-07-01140-8.
- ^ a b Laakso, T.J. (1 April 2000). "Ahlfors Q-regular spaces with arbitrary Q > 1 admitting weak Poincaré inequality". Geometric and Functional Analysis. 10 (1): 111–123. doi:10.1007/s000390050003.
- ^ Bourdon, Marc; Pajot, Hervé (9 April 1999). "Poincaré inequalities and quasiconformal structure on the boundary of some hyperbolic buildings". Proceedings of the American Mathematical Society. 127 (8): 2315–2324. arXiv:math/9710208. doi:10.1090/S0002-9939-99-04901-1.