Element (mathematics)

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In mathematics, an element or member of a set is any one of the distinct objects that make up that set.

[edit] Sets

Writing $A = {1,2,3,4}$ , means that the elements of the set $A$ are the numbers 1, 2, 3 and 4. Groups of elements of $A$ , for example ${1,2}$ , are subsets of $A$ .

Sets can themselves be elements. For example consider the set $B = {1,2,{3,4}}$ . The elements of $B$ are not 1, 2, 3, and 4. Rather, there are only three elements of $B$ , namely the numbers 1 and 2, and the set ${3,4}$ .

The elements of a set can be anything. For example, $C = {red, green, blue}$ , is the set whose elements are the colors red, green and blue.

[edit] Notation

The relation "is an element of", also called set membership, is denoted by ∈, and writing

$x \in A$

means that $x$ is an element of $A$ . Equivalently one can say or write " $x$ is a member of $A$ ", " $x$ belongs to $A$ ", " $x$ is in $A$ ", " $x$ lies in $A$ ", " $A$ includes $x$ ", or " $A$ contains $x$ ". The negation of set membership is denoted by ∉.

Unfortunately, the terms " $A$ includes $x$ " and " $A$ contains $x$ " are ambiguous, because some authors also use them to mean " $x$ is a subset of $A$ ".^[1] Logician George Boolos strongly urged that "contains" be used for membership only and "includes" for the subset relation only.^[2]

[edit] Cardinality of sets

The number of elements in a particular set is a property known as cardinality, informally this is the size of a set. In the above examples the cardinality of the set $A$ is 4, while the cardinality of the sets $B$ and $C$ is 3. An infinite set is a set with an infinite number of elements, while a finite set is a set with a finite number of elements. The above examples are examples of finite sets. An example of an infinite set is the set of natural numbers, $\mathbb{N} = \{ 1, 2, 3, 4 \ldots \}$ .

[edit] Examples

Using the sets defined above as

2 ∈ A
{3,4} ∈ B
{3,4} is a member of B
Yellow ∉ C
The cardinality of $D = {2,4,6,8,10,12}$ is finite and equal to 6.
The cardinality of $P = {2,3,5,7,11,13...}$ (the prime numbers) is infinite.

[edit] Notes

^ Eric Schechter (1997). Handbook of Analysis and Its Foundations. Academic Press. ISBN 0-12-622760-8. p. 12
^ George Boolos. "24.243 Classical Set Theory (lecture)." Massachusetts Institute of Technology, Cambridge, MA (February 4, 1992).

[edit] References

Paul R. Halmos 1960, Naive Set Theory, Springer-Verlag, NY, ISBN 0-387-90092-6. "Naive" means that it is not fully axiomatized, not that it is silly or easy (Halmos's treatment is neither).

Patrick Suppes 1960, 1972, Axiomatic Set Theory, Dover Publications, Inc. NY, ISBN 0-486-61630-4. Both the notion of set (a collection of members), membership or element-hood, the axiom of extension, the axiom of separation, and the union axiom (Suppes calls it the sum axiom) are needed for a more thorough understanding of "set element".

example set B is counting number bet. 1 & 4.

[schech-0] Eric Schechter (1997). Handbook of Analysis and Its Foundations. Academic Press. ISBN 0-12-622760-8. p. 12

[boolos-1] George Boolos. "24.243 Classical Set Theory (lecture)." Massachusetts Institute of Technology, Cambridge, MA (February 4, 1992).

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Element (mathematics)

From Wikipedia, the free encyclopedia

Contents

[edit] Sets

[edit] Notation

[edit] Cardinality of sets

[edit] Examples

[edit] Notes

[edit] References

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