Cantor Set is Uncountable/Proof 1

Proof
From the definition as a ternary representation, $\mathcal C$ consists of all the elements of $\left[{0 \,.\,.\, 1}\right]$ which can be written without using a $1$.

So let $x \in \mathcal C$. Then in base $3$ notation, we have (as $0 \le x \le 1$):


 * $\displaystyle x = \sum_{i=1}^\infty r_j 3^{-j}$

From the definition of the Cantor set, we have $\forall j: r_j \in \{0,2\}$.

Furthermore, from Representation of Ternary Expansions, the $r_j$ are unique.

Now define the following function:


 * $\displaystyle f: \mathcal C \to \left[{0 \,.\,.\, 1}\right],\quad f \left({\sum_{i=1}^\infty r_j 3^{-j}}\right) = \sum_{i=1}^\infty \frac {r_j} 2 2^{-j}$

Observe that $\forall j: \dfrac {r_j} 2 \in \{0, 1\}$.

That the right-hand expression is in fact an element of $\left[{0 \,.\,.\, 1}\right]$ now follows from binary notation.

Furthermore by Existence of Base-N Representation, any element $y$ of $\left[{0 \,.\,.\, 1}\right]$ may be written in the following form (where $\forall j: b_j \in \{0,1\}$):


 * $\displaystyle y = \sum_{i=1}^\infty b_j 2^{-j}$

Obviously, $y = f \left({x}\right)$, where $x \in \mathcal C$ is defined as follows:


 * $\displaystyle x = \sum_{i=1}^\infty 2b_j 3^{-j}$

It follows that $f$ is surjective.

From Closed Interval in Reals is Uncountable, the closed interval $\left[{0 \,.\,.\, 1}\right]$ is uncountable.

The result follows.