Cantor Set

Cantor Ternary Set

A Cantor ternary set ${\displaystyle C}$ 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 ${\displaystyle C_{0}=[0,1]}$, one can remove firstly the middle one third open interval, ${\displaystyle (1/3,2/3)}$, and get the remaining union of closed intervals ${\displaystyle C_{1}=C_{0}\setminus (1/3,2/3)=[0,1/3]\cup [2/3,1]}$. Then one can define ${\displaystyle C_{2}}$ with a similar manner: ${\displaystyle C_{2}=C_{1}\setminus ((1/9,2/9)\cup (7/9,8/9))=[0,1/9]\cup [2/9,1/3]\cup [2/3,7/9]\cup [8/9,1]}$. Consecutively, each ${\displaystyle C_{n}}$ is constructed by removing the middle one third of the closed intervals of ${\displaystyle C_{n-1}}$. The Cantor set ${\displaystyle C}$ is then defined as follows.^[1][2]

${\displaystyle C=\cup _{n=1}^{+\infty }C_{n}.}$

Properties of Cantor Sets

A Cantor set ${\displaystyle C}$ constructed with the iterating process above has the following properties.^[1]

• ${\displaystyle C}$ is compact, nowhere dense, and totally disconnected. Moreover, ${\displaystyle C}$ has no isolated points.
• Denote ${\displaystyle \lambda }$ as the Lebesgue measure and ${\displaystyle {\mathcal {B}}_{\mathbb {R} }}$ as the Borel set defined on ${\displaystyle \mathbb {R} }$. Then ${\displaystyle C}$ is measurable, and ${\displaystyle \lambda (C)=0}$.
• Cantor set is in bijection with ${\displaystyle [0,1]}$, 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