Difference between revisions of "Metric dimension"
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| − | This quantity is not yet a topological invariant. Thus, the metric order of a curve in the sense of Jordan (cf. [[Line (curve)|Line (curve)]]) with the Euclidean metric is equal to 1, but for a curve in the sense of Jordan passing through a perfect totally-disconnected set in | + | A numerical characteristic of a compact set, defined in terms of coverings of "standard measure" , the number of which defines the metric dimension. Let $ F $ |
| + | be a compact set, and let $ N _ {F} ( \epsilon ) $ | ||
| + | be the minimal number of sets with diameter not exceeding $ \epsilon $ | ||
| + | that are needed in order to cover $ F $. | ||
| + | This function, depending on the metric in $ F $, | ||
| + | takes integer values for all $ \epsilon > 0 $, | ||
| + | and increases without bound as $ \epsilon \rightarrow 0 $; | ||
| + | it is called the volume function of $ F $. | ||
| + | The metric order of the compact set $ F $ | ||
| + | is the number | ||
| + | |||
| + | $$ | ||
| + | k = fnnme \underline{lim} \ | ||
| + | \left ( | ||
| + | - | ||
| + | \frac{ \mathop{\rm ln} N _ {F} ( \epsilon ) }{ \mathop{\rm ln} \epsilon } | ||
| + | |||
| + | \right ) . | ||
| + | $$ | ||
| + | |||
| + | This quantity is not yet a topological invariant. Thus, the metric order of a curve in the sense of Jordan (cf. [[Line (curve)|Line (curve)]]) with the Euclidean metric is equal to 1, but for a curve in the sense of Jordan passing through a perfect totally-disconnected set in $ \mathbf R ^ {n} $ | ||
| + | of positive measure, this value is equal to $ n $. | ||
| + | However, the greatest lower bound of the metric orders for all metrics on $ F $( | ||
| + | called the metric dimension) is equal to the [[Lebesgue dimension|Lebesgue dimension]] (the Pontryagin–Shnirel'man theorem, 1931, see [[#References|[1]]]). | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[1]</TD> <TD valign="top"> W. Hurevicz, G. Wallman, "Dimension theory" , Princeton Univ. Press (1948)</TD></TR></table> | <table><TR><TD valign="top">[1]</TD> <TD valign="top"> W. Hurevicz, G. Wallman, "Dimension theory" , Princeton Univ. Press (1948)</TD></TR></table> | ||
| − | |||
| − | |||
====Comments==== | ====Comments==== | ||
| Line 17: | Line 46: | ||
One example is the [[Hausdorff dimension|Hausdorff dimension]]. | One example is the [[Hausdorff dimension|Hausdorff dimension]]. | ||
| − | Another example is obtained by modifying the definition of the covering dimension | + | Another example is obtained by modifying the definition of the covering dimension $ \mathop{\rm dim} $( |
| + | see [[Dimension|Dimension]]): If $ ( X , d ) $ | ||
| + | is a metric space, one defines $ \mu \mathop{\rm dim} ( X , d ) $ | ||
| + | by $ \mu \mathop{\rm dim} ( X , d ) \leq n $ | ||
| + | if and only if for every $ \epsilon > 0 $ | ||
| + | there is an open covering $ \mathfrak U $ | ||
| + | of $ X $ | ||
| + | with $ \textrm{ mesh } \mathfrak U \leq n + 1 $ | ||
| + | and $ \mathop{\rm ord} \mathfrak U < \epsilon $. | ||
| + | Here $ \textrm{ mesh } \mathfrak U = \sup \{ { \mathop{\rm diam} ( U) } : {U \in \mathfrak U } \} $ | ||
| + | and $ \mathop{\rm ord} \mathfrak U \leq n + 1 $ | ||
| + | means that no point of $ X $ | ||
| + | is an element of more than $ n + 1 $ | ||
| + | elements of $ \mathfrak U $. | ||
| + | One can show that $ \mu \mathop{\rm dim} ( X , d ) \leq \mathop{\rm dim} X \leq 2 \mu \mathop{\rm dim} ( X , d ) $ | ||
| + | and that these inequalities are best possible, see [[#References|[a1]]]. | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> R. Engelking, "Dimension theory" , North-Holland & PWN (1978) pp. 19; 50</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> J.-I. Nagata, "Modern dimension theory" , Interscience (1965)</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> R. Engelking, "Dimension theory" , North-Holland & PWN (1978) pp. 19; 50</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> J.-I. Nagata, "Modern dimension theory" , Interscience (1965)</TD></TR></table> | ||
Revision as of 08:00, 6 June 2020
A numerical characteristic of a compact set, defined in terms of coverings of "standard measure" , the number of which defines the metric dimension. Let $ F $
be a compact set, and let $ N _ {F} ( \epsilon ) $
be the minimal number of sets with diameter not exceeding $ \epsilon $
that are needed in order to cover $ F $.
This function, depending on the metric in $ F $,
takes integer values for all $ \epsilon > 0 $,
and increases without bound as $ \epsilon \rightarrow 0 $;
it is called the volume function of $ F $.
The metric order of the compact set $ F $
is the number
$$ k = fnnme \underline{lim} \ \left ( - \frac{ \mathop{\rm ln} N _ {F} ( \epsilon ) }{ \mathop{\rm ln} \epsilon } \right ) . $$
This quantity is not yet a topological invariant. Thus, the metric order of a curve in the sense of Jordan (cf. Line (curve)) with the Euclidean metric is equal to 1, but for a curve in the sense of Jordan passing through a perfect totally-disconnected set in $ \mathbf R ^ {n} $ of positive measure, this value is equal to $ n $. However, the greatest lower bound of the metric orders for all metrics on $ F $( called the metric dimension) is equal to the Lebesgue dimension (the Pontryagin–Shnirel'man theorem, 1931, see [1]).
References
| [1] | W. Hurevicz, G. Wallman, "Dimension theory" , Princeton Univ. Press (1948) |
Comments
Metric dimension makes sense for non-compact separable metrizable spaces (using totally bounded metrics), and the Pontryagin–Shnirel'man theorem extends to them. This was shown by E. Szpilrajn-Marczewski. See [a2].
There are also other types of metric-dependent dimension functions.
One example is the Hausdorff dimension.
Another example is obtained by modifying the definition of the covering dimension $ \mathop{\rm dim} $( see Dimension): If $ ( X , d ) $ is a metric space, one defines $ \mu \mathop{\rm dim} ( X , d ) $ by $ \mu \mathop{\rm dim} ( X , d ) \leq n $ if and only if for every $ \epsilon > 0 $ there is an open covering $ \mathfrak U $ of $ X $ with $ \textrm{ mesh } \mathfrak U \leq n + 1 $ and $ \mathop{\rm ord} \mathfrak U < \epsilon $. Here $ \textrm{ mesh } \mathfrak U = \sup \{ { \mathop{\rm diam} ( U) } : {U \in \mathfrak U } \} $ and $ \mathop{\rm ord} \mathfrak U \leq n + 1 $ means that no point of $ X $ is an element of more than $ n + 1 $ elements of $ \mathfrak U $. One can show that $ \mu \mathop{\rm dim} ( X , d ) \leq \mathop{\rm dim} X \leq 2 \mu \mathop{\rm dim} ( X , d ) $ and that these inequalities are best possible, see [a1].
References
| [a1] | R. Engelking, "Dimension theory" , North-Holland & PWN (1978) pp. 19; 50 |
| [a2] | J.-I. Nagata, "Modern dimension theory" , Interscience (1965) |
Metric dimension. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Metric_dimension&oldid=47828