Packing dimension explained

In mathematics, the packing dimension is one of a number of concepts that can be used to define the dimension of a subset of a metric space. Packing dimension is in some sense dual to Hausdorff dimension, since packing dimension is constructed by "packing" small open balls inside the given subset, whereas Hausdorff dimension is constructed by covering the given subset by such small open balls. The packing dimension was introduced by C. Tricot Jr. in 1982.

Definitions

Let (Xd) be a metric space with a subset S ⊆ X and let s ≥ 0 be a real number. The s-dimensional packing pre-measure of S is defined to be

s
P
0

(S)=\limsup\delta\left\{\left.\sumidiam

s
(B
i)

\right|\begin{matrix}\{Bi\}iisacountablecollection\ofpairwisedisjointclosedballswith\diameters\leq\deltaandcentresinS\end{matrix}\right\}.

Unfortunately, this is just a pre-measure and not a true measure on subsets of X, as can be seen by considering dense, countable subsets. However, the pre-measure leads to a bona fide measure: the s-dimensional packing measure of S is defined to be

Ps(S)=inf\left\{\left.\sumj

s
P
0

(Sj)\right|S\subseteqcupjSj,Jcountable\right\},

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

Having done this, the packing dimension dimP(S) of S is defined analogously to the Hausdorff dimension:

\begin{align} \dimP(S)&{}=\sup\{s\geq0|Ps(S)=+infty\}\\ &{}=inf\{s\geq0|Ps(S)=0\}. \end{align}

An example

The following example is the simplest situation where Hausdorff and packing dimensions may differ.

Fix a sequence

(an)

such that

a0=1

and

0<an+1<an/2

. Define inductively a nested sequence

E0\supsetE1\supsetE2\supset

of compact subsets of the real line as follows: Let

E0=[0,1]

. For each connected component of

En

(which will necessarily be an interval of length

an

), delete the middle interval of length

an-2an+1

, obtaining two intervals of length

an+1

, which will be taken as connected components of

En+1

. Next, define

K=capnEn

. Then

K

is topologically a Cantor set (i.e., a compact totally disconnected perfect space). For example,

K

will be the usual middle-thirds Cantor set if
-n
a
n=3
.

It is possible to show that the Hausdorff and the packing dimensions of the set

K

are given respectively by:

\begin{align} \dimH(K)&{}=\liminfn\toinfty

nlog2
-logan

,\\ \dimP(K)&{}=\limsupn\toinfty

nlog2
-logan

. \end{align}

It follows easily that given numbers

0\leqd1\leqd2\leq1

, one can choose a sequence

(an)

as above such that the associated (topological) Cantor set

K

has Hausdorff dimension

d1

and packing dimension

d2

.

Generalizations

One can consider dimension functions more general than "diameter to the s": for any function h : [0,&nbsp;+∞)&nbsp;→&nbsp;[0,&nbsp;+∞], let the packing pre-measure of S with dimension function h be given by

h
P
0

(S)=\lim\delta\sup\left\{\left.\sumih(diam(Bi))\right|\begin{matrix}\{Bi\}iisacountablecollection\ofpairwisedisjointballswith\diameters\leq\deltaandcentresinS\end{matrix}\right\}

and define the packing measure of S with dimension function h by

Ph(S)=inf\left\{\left.\sumj

h
P
0

(Sj)\right|S\subseteqcupjSj,Jcountable\right\}.

The function h is said to be an exact (packing) dimension function for S if Ph(S) is both finite and strictly positive.

Properties

Note, however, that the packing dimension is not equal to the box dimension. For example, the set of rationals Q has box dimension one and packing dimension zero.

See also

References