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Not all uncountable sets have the same size; the sizes of infinite sets are analyzed with the theory of Cardinal Number s. Formally, an uncountable set is defined as one whose Cardinality is strictly greater than \aleph_0 ( Aleph-null , the cardinality of the Natural Number s).

The best known example of an uncountable set is the set R of all Real Number s; Cantor's Diagonal Argument shows that this set is uncountable. The diagonalization proof technique can also be used to show that several other sets are uncountable as well, for instance the set of all infinite Sequence s of Natural Number s (and even the set of all infinite sequences consisting only of zeros and ones) and the set of all Subset s of natural numbers. The cardinality of R is often called the Cardinality Of The Continuum and denoted by ''c'' or \beth_1 ( Beth-one ).

The Cantor Set is an uncountable subset of R. The Cantor set is a Fractal and has Hausdorff Dimension greater than zero but less than one (R has dimension one). This is an example of the following fact: any subset of R of Hausdorff dimension strictly greater than zero must be uncountable.

Another example of an uncountable set is the set of all functions from R to R. It is not hard to believe that this set is even "more uncountable" than R. The cardinality of this set is \beth_2 ( Beth-two ) and is, indeed, larger than \beth_1.

A much more abstract example of an uncountable set is the set of all countable Ordinal Number s, denoted Ω. The cardinality of Ω is denoted \aleph_1 ( Aleph-one ). It can be shown that \aleph_1 is the ''smallest'' uncountable cardinal number. One might naturally wonder whether \beth_1, the cardinality of the reals, is equal to \aleph_1 or if it is strictly larger. The statement that \aleph_1 = \beth_1 is called the Continuum Hypothesis . This hypothesis is now known to be independent from the ordinary axioms of Set Theory (cf. Zermelo-Frankel Axioms ). Which is to say, that one can either assume the continuum hypothesis is true, or assume that is false without running into any contradictions.


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