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.

References

  1. 1.0 1.1 Gerald B. Folland, Real Analysis: Modern Techniques and Their Applications, second edition, §1.5
  2. Craig, Katy. MATH 201A HW 5. UC Santa Barbara, Fall 2020.