Cantor set: Difference between revisions

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The '''Cantor set''' is a [[topological]] space which may be obtained as a [[fractal]] generated by removing the middle third of a [[line segment]] on each iteration: as such it has a [[Hausdorff dimension]] of [[Natural logarithm|ln]](2)/ln(3), which is approximately 0.63.
The '''Cantor set''' is a set that may be generated by removing the middle third of a [[line segment]] on each iteration. It is a [[fractal]] with a [[Hausdorff dimension]] of [[Natural logarithm|ln]](2)/ln(3), which is approximately 0.63.


==Topological properties==
==Topological properties==
The Cantor set is [[homeomorphism|homeomorphic]] to a product of [[countable set|countably]] many copies of a two-point space with the [[discrete metric]].  It is thus [[compact space|compact]].  It may be realised as the space of binary sequences  
The Cantor set may be considered a [[topological space]], [[homeomorphism|homeomorphic]] to a product of [[countable set|countably]] many copies of a two-point space with the [[discrete topology]].  It is thus [[compact space|compact]].  It may be realised as the space of binary sequences  


:<math> C = \left\lbrace (x_n)_{n \in \mathbf{N}} : x_n \in \{0,1\} \right\rbrace , \,</math>
:<math> C = \left\lbrace (x_n)_{n \in \mathbf{N}} : x_n \in \{0,1\} \right\rbrace , \,</math>
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in which the open sets are generated by the ''cylinders'', of the form
in which the open sets are generated by the ''cylinders'', of the form


:<math> C_s = \left\lbrace (x_n) \in C : x_n = s_n for n=0,\ldots,k-1 \right\rbrace , \,</math>
:<math> C_s = \left\lbrace (x_n) \in C : x_n = s_n \mbox{ for } n=0,\ldots,k-1 \right\rbrace , \,</math>


where ''s'' is a given binary sequence of length ''k''.
where ''s'' is a given binary sequence of length ''k''.


The Cantor set is [[uncountable set|uncountable]], [[compact space|compact]], [[second countable space|second countable]], dense-in-itself, [[totally disconnected space|totally disconnected]].
As a topological space, the Cantor set is [[uncountable set|uncountable]], [[compact space|compact]], [[second countable space|second countable]] and [[totally disconnected space|totally disconnected]].


==Metric properties==
==Metric properties==
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where <math>d_2</math> is the discrete metric on ''D''.
where <math>d_2</math> is the discrete metric on ''D''.


The Cantor set is [[completeness (mathematics|complete]] with respect to ''d''.
The Cantor set is a [[complete metric space]] with respect to ''d''.


==Embedding in the unit interval==
==Embedding in the unit interval==
The Cantor set may be embedded in the unit interval by the map
The Cantor set may be embedded in the [[unit interval]] by the map


:<math>f : \mathbf{x} \mapsto \sum_{n=0}^\infty 2x_n.3^{-n-1} </math>
:<math>f : \mathbf{x} \mapsto \sum_{n=0}^\infty 2x_n.3^{-n-1} </math>


which is a homeomorphism onto the subset of the unit interval obtained by iteratively deleting the middle third of each interval.
which is a homeomorphism onto the subset of the unit interval obtained by iteratively deleting the middle third of each interval. As a subset of the unit interval it is [[closed set|closed]], [[nowhere dense set|nowhere dense]], [[perfect set|perfect]] and [[dense-in-itself set|dense-in-itself]].  It has [[Lebesgue measure]] zero.[[Category:Suggestion Bot Tag]]

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The Cantor set is a set that may be generated by removing the middle third of a line segment on each iteration. It is a fractal with a Hausdorff dimension of ln(2)/ln(3), which is approximately 0.63.

Topological properties

The Cantor set may be considered a topological space, homeomorphic to a product of countably many copies of a two-point space with the discrete topology. It is thus compact. It may be realised as the space of binary sequences

in which the open sets are generated by the cylinders, of the form

where s is a given binary sequence of length k.

As a topological space, the Cantor set is uncountable, compact, second countable and totally disconnected.

Metric properties

The topology on the countable product of the two-point space D is induced by the metric

where is the discrete metric on D.

The Cantor set is a complete metric space with respect to d.

Embedding in the unit interval

The Cantor set may be embedded in the unit interval by the map

which is a homeomorphism onto the subset of the unit interval obtained by iteratively deleting the middle third of each interval. As a subset of the unit interval it is closed, nowhere dense, perfect and dense-in-itself. It has Lebesgue measure zero.