3.4 *The Cantor Set 165
Thus, C2 = [O, i] urn,~] u [~, ~] u [~, 1].
Continuing inductively, if Cn is the union of 2n disjoint closed intervals
of length 3 ~ , we define Cn+I to be the result of removing from Cn the open
middle thirds of these intervals, each of length 3 !+ 1 • For example,
C3 = [o, 2 ~] U [ 227 , i] U [~, J 7 ] u [ 287 , ~] u [~, ~~] U [;~, ~] U [;~, ;~] u [;*, l].
At each stage, to get Cn+I we remove the open middle thirds of the 2n
disjoint closed intervals comprising Cn, and Cn+I is the union of the resulting
2n+l disjoint closed intervals, each of length 3 n\ 1 • Notice that
C1 2 C2 2. .. 2 Cn 2 Cn+I 2 .. ..
We define the Cantor set to be
00
C = n Cn.
n=l
That is , C is what is left over in [O, 1] after removing successively all the "open
middle third" sets, as described above. · D
Theorem 3.4.2 The Cantor set is compact.
Proof. Exercise 1. •
Theorem 3.4.3 The Cantor set contains no nonempty open interval.
Proof. Exercise 2. •
THE CANTOR SET AND TERNARY DECIMALS
Let us consider what numbers belong to the Cantor set. The Cantor set is
clearly nonempty; for example, ~ E C. In fact,
Lemma 3.4.4 If a is an endpoint of one of the disjoint closed intervals com-
prising some Cn, then a EC.
Proof. Exercise 4. •
To characterize the numbers that belong to the Cantor set C , we resort
to ternary (base-three) decimal-like representation of real numbers. While the
word "decimal" signals base-ten, any natural number b > 1 can be used to
represent real numbers in decimal-like form. For lack of a better term, we shall
refer to these expressions as base-b decimals.
Definition 3.4.5 (Base-b "Decimals") Let b be any natural number greater
than 1. Then a "base-b decimal" is any expression of the form
K.d1d2 · · · dndn+I · · · (base b) or
-K.d1d 2 · · · dndn+I · · · (base b)
where K is a natural number and Vi EN, di E {O, 1, 2, · · · , b - l}.