Cantor Set: Difference between revisions
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==Cantor Function== | ==Cantor Function== | ||
The Cantor set can be used to define [[Cantor Function]]. | The Cantor set can be used to define [[Cantor Function]], an increasing function which is continuous but has zero derivative almost everywhere. | ||
==References== | ==References== |
Revision as of 03:01, 18 December 2020
Cantor Ternary Set
A Cantor ternary set of base-3 can be constructed through the infinite process of removing the middle one third of the open intervals from each closed interval composing the previous constructing sets sequentially. Specifically, starting from a closed interval , one can remove firstly the middle one third open interval, , and get the remaining union of closed intervals . Then one can define with a similar manner: . Consecutively, each is constructed by removing the middle one third of the closed intervals of . The Cantor set is then defined as follows.[1][2]
Properties of Cantor Sets
A Cantor set constructed with the iterating process above has the following properties.[1]
- is compact, nowhere dense, and totally disconnected. Moreover, has no isolated points.
- Denote as the Lebesgue measure and as the Borel set defined on . Then is measurable, and .
- Cantor set is in bijection with , giving us a counterexample of a noncountable set having zero measure.
Cantor Function
The Cantor set can be used to define Cantor Function, an increasing function which is continuous but has zero derivative almost everywhere.