Uncountable set

Last updated December 01, 2024

In mathematics, an uncountable set, informally, is an infinite set that contains too many elements to be countable. The uncountability of a set is closely related to its cardinal number: a set is uncountable if its cardinal number is larger than aleph-null, the cardinality of the natural numbers.

Characterizations

There are many equivalent characterizations of uncountability. A set X is uncountable if and only if any of the following conditions hold:

There is no injective function (hence no bijection) from X to the set of natural numbers.
X is nonempty and for every ω-sequence of elements of X, there exists at least one element of X not included in it. That is, X is nonempty and there is no surjective function from the natural numbers to X.
The cardinality of X is neither finite nor equal to $\aleph _{0}$ (aleph-null).
The set X has cardinality strictly greater than $\aleph _{0}$ .

The first three of these characterizations can be proven equivalent in Zermelo–Fraenkel set theory without the axiom of choice, but the equivalence of the third and fourth cannot be proved without additional choice principles.

Properties

If an uncountable set X is a subset of set Y, then Y is uncountable.

Examples

The best known example of an uncountable set is the set ⁠ $\mathbb {R}$ ⁠ of all real numbers; 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, such as the set of all infinite sequences of natural numbers ⁠ $\mathbb {N}$ ⁠, and the set of all subsets of the set of natural numbers. The cardinality of ⁠ $\mathbb {R}$ ⁠ is often called the cardinality of the continuum, and denoted by ${\mathfrak {c}}$ , or $2^{\aleph _{0}}$ , or $\beth _{1}$ (beth-one).

The Cantor set is an uncountable subset of ⁠ $\mathbb {R}$ ⁠. The Cantor set is a fractal and has Hausdorff dimension greater than zero but less than one (⁠ $\mathbb {R}$ ⁠ has dimension one). This is an example of the following fact: any subset of ⁠ $\mathbb {R}$ ⁠ of Hausdorff dimension strictly greater than zero must be uncountable.

Another example of an uncountable set is the set of all functions from ⁠ $\mathbb {R}$ ⁠ to ⁠ $\mathbb {R}$ ⁠. This set is even "more uncountable" than ⁠ $\mathbb {R}$ ⁠ in the sense that the cardinality of this set is $\beth _{2}$ (beth-two), which is larger than $\beth _{1}$ .

A more abstract example of an uncountable set is the set of all countable ordinal numbers, denoted by Ω or ω₁.^[1] The cardinality of Ω is denoted $\aleph _{1}$ (aleph-one). It can be shown, using the axiom of choice, that $\aleph _{1}$ is the smallest uncountable cardinal number. Thus either $\beth _{1}$ , the cardinality of the reals, is equal to $\aleph _{1}$ or it is strictly larger. Georg Cantor was the first to propose the question of whether $\beth _{1}$ is equal to $\aleph _{1}$ . In 1900, David Hilbert posed this question as the first of his 23 problems. The statement that $\aleph _{1}=\beth _{1}$ is now called the continuum hypothesis, and is known to be independent of the Zermelo–Fraenkel axioms for set theory (including the axiom of choice).

Without the axiom of choice

Without the axiom of choice, there might exist cardinalities incomparable to $\aleph _{0}$ (namely, the cardinalities of Dedekind-finite infinite sets). Sets of these cardinalities satisfy the first three characterizations above, but not the fourth characterization. Since these sets are not larger than the natural numbers in the sense of cardinality, some may not want to call them uncountable.

If the axiom of choice holds, the following conditions on a cardinal $\kappa$ are equivalent:

$\kappa \nleq \aleph _{0};$
$\kappa >\aleph _{0};$ and
$\kappa \geq \aleph _{1}$ , where $\aleph _{1}=|\omega _{1}|$ and $\omega _{1}$ is the least initial ordinal greater than $\omega .$

However, these may all be different if the axiom of choice fails. So it is not obvious which one is the appropriate generalization of "uncountability" when the axiom fails. It may be best to avoid using the word in this case and specify which of these one means.

Related Research Articles

In mathematics, specifically set theory, the continuum hypothesis is a hypothesis about the possible sizes of infinite sets. It states:

"There is no set whose cardinality is strictly between that of the integers and the real numbers."

<span class="mw-page-title-main">Cardinal number</span> Size of a possibly infinite set

In mathematics, a cardinal number, or cardinal for short, is what is commonly called the number of elements of a set. In the case of a finite set, its cardinal number, or cardinality is therefore a natural number. For dealing with the case of infinite sets, the infinite cardinal numbers have been introduced, which are often denoted with the Hebrew letter $(aleph) marked with subscript indicating their rank among the infinite cardinals.$

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In the mathematical discipline of set theory, 0^# is the set of true formulae about indiscernibles and order-indiscernibles in the Gödel constructible universe. It is often encoded as a subset of the natural numbers, or as a subset of the hereditarily finite sets, or as a real number. Its existence is unprovable in ZFC, the standard form of axiomatic set theory, but follows from a suitable large cardinal axiom. It was first introduced as a set of formulae in Silver's 1966 thesis, later published as Silver (1971), where it was denoted by Σ, and rediscovered by Solovay, who considered it as a subset of the natural numbers and introduced the notation O^#.

<span class="mw-page-title-main">Aleph number</span> Infinite cardinal number

In mathematics, particularly in set theory, the aleph numbers are a sequence of numbers used to represent the cardinality of infinite sets that can be well-ordered. They were introduced by the mathematician Georg Cantor and are named after the symbol he used to denote them, the Hebrew letter aleph (ℵ).

In mathematics, two sets or classes A and B are equinumerous if there exists a one-to-one correspondence (or bijection) between them, that is, if there exists a function from A to B such that for every element y of B, there is exactly one element x of A with f(x) = y. Equinumerous sets are said to have the same cardinality (number of elements). The study of cardinality is often called equinumerosity (equalness-of-number). The terms equipollence (equalness-of-strength) and equipotence (equalness-of-power) are sometimes used instead.

In mathematics, limit cardinals are certain cardinal numbers. A cardinal number λ is a weak limit cardinal if λ is neither a successor cardinal nor zero. This means that one cannot "reach" λ from another cardinal by repeated successor operations. These cardinals are sometimes called simply "limit cardinals" when the context is clear.

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In set theory, one can define a successor operation on cardinal numbers in a similar way to the successor operation on the ordinal numbers. The cardinal successor coincides with the ordinal successor for finite cardinals, but in the infinite case they diverge because every infinite ordinal and its successor have the same cardinality. Using the von Neumann cardinal assignment and the axiom of choice (AC), this successor operation is easy to define: for a cardinal number κ we have

In mathematics, particularly in set theory, the beth numbers are a certain sequence of infinite cardinal numbers, conventionally written $, where is the Hebrew letter beth. The beth numbers are related to the aleph numbers, but unless the generalized continuum hypothesis is true, there are numbers indexed by that are not indexed by .$

In set theory, the cardinality of the continuum is the cardinality or "size" of the set of real numbers $, sometimes called the continuum. It is an infinite cardinal number and is denoted by or$

In model theory, a branch of mathematical logic, the spectrum of a theory is given by the number of isomorphism classes of models in various cardinalities. More precisely, for any complete theory T in a language we write I(T, κ) for the number of models of T (up to isomorphism) of cardinality κ. The spectrum problem is to describe the possible behaviors of I(T, κ) as a function of κ. It has been almost completely solved for the case of a countable theory T.

In mathematics, infinitary combinatorics, or combinatorial set theory, is an extension of ideas in combinatorics to infinite sets. Some of the things studied include continuous graphs and trees, extensions of Ramsey's theorem, and Martin's axiom. Recent developments concern combinatorics of the continuum and combinatorics on successors of singular cardinals.

In mathematics, the first uncountable ordinal, traditionally denoted by $or sometimes by, is the smallest ordinal number that, considered as a set, is uncountable. It is the supremum of all countable ordinals. When considered as a set, the elements of are the countable ordinals, of which there are uncountably many.$

In set theory, an ordinal number, or ordinal, is a generalization of ordinal numerals aimed to extend enumeration to infinite sets.

In mathematics, more specifically in general topology, the Tychonoff cube is the generalization of the unit cube from the product of a finite number of unit intervals to the product of an infinite, even uncountable number of unit intervals. The Tychonoff cube is named after Andrey Tychonoff, who first considered the arbitrary product of topological spaces and who proved in the 1930s that the Tychonoff cube is compact. Tychonoff later generalized this to the product of collections of arbitrary compact spaces. This result is now known as Tychonoff's theorem and is considered one of the most important results in general topology.

This is a glossary of terms and definitions related to the topic of set theory.

References

↑ Weisstein, Eric W. "Uncountably Infinite". mathworld.wolfram.com. Retrieved 2020-09-05.

Bibliography

Halmos, Paul, Naive Set Theory . Princeton, NJ: D. Van Nostrand Company, 1960. Reprinted by Springer-Verlag, New York, 1974. ISBN 0-387-90092-6 (Springer-Verlag edition). Reprinted by Martino Fine Books, 2011. ISBN 978-1-61427-131-4 (Paperback edition).
Jech, Thomas (2002), Set Theory, Springer Monographs in Mathematics (3rd millennium ed.), Springer, ISBN 3-540-44085-2

External links

Proof that R is uncountable

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[:0-1] Weisstein, Eric W. "Uncountably Infinite". mathworld.wolfram.com. Retrieved 2020-09-05.

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