User:IntegralPython/sandbox/Fractal measure

Fractal measure is any measure which generalizes the notions of length, area, and volume to non-integer dimensions, especially in application towards fractals. There is no unique fractal measure, in part although not entirely due to the lack of a unique definition of fractal dimension; the most common fractal measures include the Hausdorff measure and the packing measure, based off of the Hausdorff dimension and packing dimension respectively.^[1] Fractal measures are measures in the sense of measure theory, and are usually defined to agree with the n-dimensional Lebesgue measure when n is an integer.^[2] Fractal measure can be used to define the fractal dimension or vice versa. Although related, differing fractal measures are not equivalent, and may provide different measurements for the same shape.

A Carathéodory construction is a constructive method of building fractal measures, used to create measures from similarly defined outer measures.

Let τ : Σ → [0, +∞] be a set function defined on a class Σ of subsets of X containing the empty set ∅, such that τ(∅) = 0. One can show that the set function μ defined by^[3]

${\displaystyle \mu (E)=\lim _{\delta \to 0}\mu _{\delta }(E),}$

where

${\displaystyle \mu _{\delta }(E)=\inf \left\{\left.\sum _{i=1}^{\infty }\tau (C_{i})\right|C_{i}\in \Sigma ,\mathrm {diam} (C_{i})\leq \delta ,\bigcup _{i=1}^{\infty }C_{i}\supseteq E\right\},}$

is not only an outer measure, but in fact a metric outer measure as well. (Some authors prefer to take a supremum over δ > 0 rather than a limit as δ → 0; the two give the same result, since μ_δ(E) increases as δ decreases.)

The function and domain of τ may determine the specific measure obtained. For instance, if we give

${\displaystyle \tau (C)=\mathrm {diam} (C)^{s},\,}$

where s is a positive constant and where τ is defined on the power set of all subsets of X (i.e., ${\displaystyle \Sigma =2^{X}}$), the associated measure μ is the s-dimensional Hausdorff measure. More generally, one could use any so-called dimension function. If instead τ is defined only on balls of X, the associated measure is the spherical measure.

This construction is how the Hausdorff and packing measures are obtained.

The Hasudorff measure is the most-used fractal measure and provides a definition for Hausdorff dimension, which is in turn one of the most frequently used definitions of fractal dimension. Intuitively, the Hausdorff measure is a covering the set by other sets, and taking the smallest possible measure of the coverings as the they approach zero.

When the d-dimensional Hausdorff measure is an integer, ${\displaystyle H^{d}(S)}$ is proportional to the Lebesgue measure for that dimension. Due to this, some definitions of Hausdorff measure include a scaling by the volume of the unit d-ball, expressed using Euler's gamma function as

${\displaystyle {\frac {\pi ^{d/2}}{\Gamma ({\frac {d}{2}}+1)}}.}$^[4]

Just as the packing dimension is in some ways a dual to the Hausdorff dimension, the packing measure is a counterpart to the Hausdorff measure. The packing measure is defined informally as the measure of "packing" a set with open balls, and calculating the measure of those balls.

Let (X, d) be a metric space with a subset S ⊆ X and let s ≥ 0. We take a "pre-measure" of S, defined to be

${\displaystyle P_{0}^{s}(S)=\limsup _{\delta \downarrow 0}\left\{\left.\sum _{i\in I}\mathrm {diam} (B_{i})^{s}\right|{\begin{matrix}\{B_{i}\}_{i\in I}{\text{ is a countable collection}}\\{\text{of pairwise disjoint closed balls with}}\\{\text{diameters }}\leq \delta {\text{ and centres in }}S\end{matrix}}\right\}.}$^[5]

The pre-measure is made into a true measure, where the s-dimensional packing measure of S is defined to be

${\displaystyle P^{s}(S)=\inf \left\{\left.\sum _{j\in J}P_{0}^{s}(S_{j})\right|S\subseteq \bigcup _{j\in J}S_{j},J{\text{ countable}}\right\},}$

i.e., the packing measure of S is the infimum of the packing pre-measures of countable covers of S.

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