In axiomatic set theory and the branches of

logic Logic is the study of correct reasoning. It includes both formal and informal logic. Formal logic is the science of deductively valid inferences or of logical truths. It is a formal science investigating how conclusions follow from premise ...

, mathematics, and

computer science Computer science is the study of computation, automation, and information. Computer science spans theoretical disciplines (such as algorithms, theory of computation, information theory, and automation) to practical disciplines (includi ...

that use it, the axiom of extensionality, or axiom of extension, is one of the axioms of

Zermelo–Fraenkel set theory In set theory, Zermelo–Fraenkel set theory, named after mathematicians Ernst Zermelo and Abraham Fraenkel, is an axiomatic system that was proposed in the early twentieth century in order to formulate a theory of sets free of paradoxes such ...

. It says that sets having the same elements are the same set.

Formal statement

In the

formal language In logic, mathematics, computer science, and linguistics, a formal language consists of words whose letters are taken from an alphabet and are well-formed according to a specific set of rules. The alphabet of a formal language consists of sy ...

of the Zermelo–Fraenkel axioms, the axiom reads: :

\forall A \, \forall B \, ( \forall X \, (X \in A \iff X \in B) \implies A = B)

or in words: :

Given any In mathematical logic, a universal quantification is a type of quantifier, a logical constant which is interpreted as "given any" or "for all". It expresses that a predicate can be satisfied by every member of a domain of discourse. In other ...

set ''A'' and any set ''B'', if for every set ''X'', ''X'' is a member of ''A''

if and only if In logic and related fields such as mathematics and philosophy, "if and only if" (shortened as "iff") is a biconditional logical connective between statements, where either both statements are true or both are false. The connective is b ...

''X'' is a member of ''B'', then ''A'' is equal to ''B''. :(It is not really essential that ''X'' here be a ''set'' — but in ZF, everything is. See Ur-elements below for when this is violated.) The converse,

\forall A \, \forall B \, (A = B \implies \forall X \, (X \in A \iff X \in B) ),

of this axiom follows from the substitution property of

equality Equality may refer to: Society * Political equality, in which all members of a society are of equal standing ** Consociationalism, in which an ethnically, religiously, or linguistically divided state functions by cooperation of each group's elit ...

Interpretation

To understand this axiom, note that the clause in parentheses in the symbolic statement above simply states that ''A'' and ''B'' have precisely the same members. Thus, what the axiom is really saying is that two sets are equal

they have precisely the same members. The essence of this is: :A set is determined uniquely by its members. The axiom of extensionality can be used with any statement of the form

\exists A \, \forall X \, (X \in A \iff P(X) \, )

, where ''P'' is any unary

predicate Predicate or predication may refer to: * Predicate (grammar), in linguistics * Predication (philosophy) * several closely related uses in mathematics and formal logic: **Predicate (mathematical logic) **Propositional function **Finitary relation, o ...

that does not mention ''A'', to define a unique set

A

whose members are precisely the sets satisfying the predicate

P

. We can then introduce a new symbol for

A

; it's in this way that definitions in ordinary mathematics ultimately work when their statements are reduced to purely set-theoretic terms. The axiom of extensionality is generally uncontroversial in set-theoretical foundations of mathematics, and it or an equivalent appears in just about any alternative axiomatisation of set theory. However, it may require modifications for some purposes, as below.

In predicate logic without equality

The axiom given above assumes that equality is a primitive symbol in

predicate logic First-order logic—also known as predicate logic, quantificational logic, and first-order predicate calculus—is a collection of formal systems used in mathematics, philosophy, linguistics, and computer science. First-order logic uses quantifie ...

. Some treatments of axiomatic set theory prefer to do without this, and instead treat the above statement not as an axiom but as a ''definition'' of equality. Then it is necessary to include the usual axioms of equality from predicate logic as axioms about this defined symbol. Most of the axioms of equality still follow from the definition; the remaining one is the substitution property, :

\forall A \, \forall B \, ( \forall X \, (X \in A \iff X \in B) \implies \forall Y \, (A \in Y \iff B \in Y) \, ),

and it becomes ''this'' axiom that is referred to as the axiom of extensionality in this context.

In set theory with ur-elements

ur-element In set theory, a branch of mathematics, an urelement or ur-element (from the German prefix ''ur-'', 'primordial') is an object that is not a set, but that may be an element of a set. It is also referred to as an atom or individual. Theory There ...

is a member of a set that is not itself a set. In the Zermelo–Fraenkel axioms, there are no ur-elements, but they are included in some alternative axiomatisations of set theory. Ur-elements can be treated as a different

logical type In mathematics, logic, and computer science, a type theory is the formal presentation of a specific type system, and in general type theory is the academic study of type systems. Some type theories serve as alternatives to set theory as a foun ...

from sets; in this case,

B \in A

makes no sense if

A

is an ur-element, so the axiom of extensionality simply applies only to sets. Alternatively, in untyped logic, we can require

B \in A

to be false whenever

A

is an ur-element. In this case, the usual axiom of extensionality would then imply that every ur-element is equal to the empty set. To avoid this consequence, we can modify the axiom of extensionality to apply only to nonempty sets, so that it reads: :

\forall A \, \forall B \, ( \exists X \, (X \in A) \implies \forall Y \, (Y \in A \iff Y \in B) \implies A = B \, ).

That is: :Given any set ''A'' and any set ''B'', ''if ''A'' is a nonempty set'' (that is, if there exists a member ''X'' of ''A''), ''then'' if ''A'' and ''B'' have precisely the same members, then they are equal. Yet another alternative in untyped logic is to define

A

itself to be the only element of

A

whenever

A

is an ur-element. While this approach can serve to preserve the axiom of extensionality, the

axiom of regularity In mathematics, the axiom of regularity (also known as the axiom of foundation) is an axiom of Zermelo–Fraenkel set theory that states that every non-empty set ''A'' contains an element that is disjoint from ''A''. In first-order logic, the ...

will need an adjustment instead.

References

Paul Halmos Paul Richard Halmos ( hu, Halmos Pál; March 3, 1916 – October 2, 2006) was a Hungarian-born American mathematician and statistician who made fundamental advances in the areas of mathematical logic, probability theory, statistics, operator ...

, ''Naive set theory''. Princeton, NJ: D. Van Nostrand Company, 1960. Reprinted by Springer-Verlag, New York, 1974. (Springer-Verlag edition). * Jech, Thomas, 2003. ''Set Theory: The Third Millennium Edition, Revised and Expanded''. Springer. . * Kunen, Kenneth, 1980. ''Set Theory: An Introduction to Independence Proofs''. Elsevier. . {{Set theory Axioms of set theory Urelements

Formal statement

Interpretation

In predicate logic without equality

In set theory with ur-elements

See also

References