Non-end points of Cantor ternary set

Any real number between $0$ and $1$ whose ternary expansion doesn't have any $1$s is in the Cantor set. So, for example, each of the following ternary expansions corresponds to a point in the Cantor set:

• $0.2020202020...$

• $0.220022002200...$

• $0.202200222000...$

and so forth. It's easy to check that these don't correspond to endpoints of the Cantor set.

Noah Schweber's answer gives a complete characterization of points in the Cantor set. A point is an endpoint if it eventually ends in all 0s or all 2s. Otherwise, it is a non-endpoint.

I'll just add a couple other ideas:

The Cantor set has some nice symmetries, like $x\mapsto \frac13 x$ and $x\mapsto 1-x$. These linear symmetries preserve endpoint-ness. So if you know that $\frac14$ is a non-endpoint, then you also know that $\frac{3}{4}$ and $\frac{1}{12}$ and $\frac{11}{12}$ and so on are non-endpoints. Similarly, $\frac{3}{10}$ gets you $\frac{1}{10},\frac{7}{10},\frac{9}{10},\frac{1}{30},$ and so on.

Finally, as Noah's third example illustrates, you can use ternary expansions to describe concrete irrational elements of $C\setminus A$ as well. For another example, we have $\theta\left(\frac13\right)-1=0.2002000020000002\ldots_3\in C\setminus A$. See my answer here for the meaning of the $\theta$ notation: Which irrationals are contained in the Cantor set?

Any element $Z$ in the Cantor Set can be written as :

$Z= \sum_{n=1}^\infty x_n/3^n$ where $x_n=0$ or $2$.

You can substitute any combination of $0,2$ and have your number belonging to the cantor set