Definition edit

If A is a set, then the absolute complement of A (or simply the complement of A) is the set of elements not in A (within a larger set that is implicitly defined). In other words, let U be a set that contains all the elements under study; if there is no need to mention U, either because it has been previously specified, or it is obvious and unique, then the absolute complement of A is the relative complement of A in U:^[3]

The absolute complement of A is usually denoted by ${\displaystyle A^{\complement }}$ . Other notations include ${\displaystyle {\overline {A}},A',}$ ^[2] ${\displaystyle \complement _{U}A,{\text{ and }}\complement A.}$ ^[4]

Examples edit

• Assume that the universe is the set of integers. If A is the set of odd numbers, then the complement of A is the set of even numbers. If B is the set of multiples of 3, then the complement of B is the set of numbers congruent to 1 or 2 modulo 3 (or, in simpler terms, the integers that are not multiples of 3).
• Assume that the universe is the standard 52-card deck. If the set A is the suit of spades, then the complement of A is the union of the suits of clubs, diamonds, and hearts. If the set B is the union of the suits of clubs and diamonds, then the complement of B is the union of the suits of hearts and spades.
• When the universe is the universe of sets described in formalized set theory, the absolute complement of a set is generally not itself a set, but rather a proper class. For more info, see universal set.

Properties edit

Let A and B be two sets in a universe U. The following identities capture important properties of absolute complements:

De Morgan's laws:^[5]

• ${\displaystyle \left(A\cup B\right)^{\complement }=A^{\complement }\cap B^{\complement }.}$ 
• ${\displaystyle \left(A\cap B\right)^{\complement }=A^{\complement }\cup B^{\complement }.}$ 

Complement laws:^[5]

• ${\displaystyle A\cup A^{\complement }=U.}$ 
• ${\displaystyle A\cap A^{\complement }=\emptyset .}$ 
• ${\displaystyle \emptyset ^{\complement }=U.}$ 
• ${\displaystyle U^{\complement }=\emptyset .}$ 
• ${\displaystyle {\text{If }}A\subseteq B{\text{, then }}B^{\complement }\subseteq A^{\complement }.}$ 

  (this follows from the equivalence of a conditional with its contrapositive).

Involution or double complement law:

• ${\displaystyle \left(A^{\complement }\right)^{\complement }=A.}$ 

Relationships between relative and absolute complements:

• ${\displaystyle A\setminus B=A\cap B^{\complement }.}$ 
• ${\displaystyle (A\setminus B)^{\complement }=A^{\complement }\cup B=A^{\complement }\cup (B\cap A).}$ 

Relationship with a set difference:

• ${\displaystyle A^{\complement }\setminus B^{\complement }=B\setminus A.}$ 

The first two complement laws above show that if A is a non-empty, proper subset of U, then {A, A^∁} is a partition of U.

Definition edit

If A and B are sets, then the relative complement of A in B,^[5] also termed the set difference of B and A,^[6] is the set of elements in B but not in A.

The relative complement of A in B is denoted ${\displaystyle B\setminus A}$  according to the ISO 31-11 standard. It is sometimes written ${\displaystyle B-A,}$  but this notation is ambiguous, as in some contexts (for example, Minkowski set operations in functional analysis) it can be interpreted as the set of all elements ${\displaystyle b-a,}$  where b is taken from B and a from A.

Formally:

Examples edit

• ${\displaystyle \{1,2,3\}\setminus \{2,3,4\}=\{1\}.}$ 
• ${\displaystyle \{2,3,4\}\setminus \{1,2,3\}=\{4\}.}$ 
• If ${\displaystyle \mathbb {R} }$  is the set of real numbers and ${\displaystyle \mathbb {Q} }$  is the set of rational numbers, then ${\displaystyle \mathbb {R} \setminus \mathbb {Q} }$  is the set of irrational numbers.

Properties edit

Let A, B, and C be three sets. The following identities capture notable properties of relative complements:

• ${\displaystyle C\setminus (A\cap B)=(C\setminus A)\cup (C\setminus B).}$ 
• ${\displaystyle C\setminus (A\cup B)=(C\setminus A)\cap (C\setminus B).}$ 
• ${\displaystyle C\setminus (B\setminus A)=(C\cap A)\cup (C\setminus B),}$ 

  with the important special case ${\displaystyle C\setminus (C\setminus A)=(C\cap A)}$  demonstrating that intersection can be expressed using only the relative complement operation.

• ${\displaystyle (B\setminus A)\cap C=(B\cap C)\setminus A=B\cap (C\setminus A).}$ 
• ${\displaystyle (B\setminus A)\cup C=(B\cup C)\setminus (A\setminus C).}$ 
• ${\displaystyle A\setminus A=\emptyset .}$ 
• ${\displaystyle \emptyset \setminus A=\emptyset .}$ 
• ${\displaystyle A\setminus \emptyset =A.}$ 
• ${\displaystyle A\setminus U=\emptyset .}$ 
• If ${\displaystyle A\subset B}$ , then ${\displaystyle C\setminus A\supset C\setminus B}$ .
• ${\displaystyle A\supseteq B\setminus C}$  is equivalent to ${\displaystyle C\supseteq B\setminus A}$ .

A binary relation ${\displaystyle R}$  is defined as a subset of a product of sets ${\displaystyle X\times Y.}$  The complementary relation ${\displaystyle {\bar {R}}}$  is the set complement of ${\displaystyle R}$  in ${\displaystyle X\times Y.}$  The complement of relation ${\displaystyle R}$  can be written

Together with composition of relations and converse relations, complementary relations and the algebra of sets are the elementary operations of the calculus of relations.

In the LaTeX typesetting language, the command \setminus^[7] is usually used for rendering a set difference symbol, which is similar to a backslash symbol. When rendered, the \setminus command looks identical to \backslash, except that it has a little more space in front and behind the slash, akin to the LaTeX sequence \mathbin{\backslash}. A variant \smallsetminus is available in the amssymb package, but this symbol is not included separately in Unicode. The symbol ${\displaystyle \complement }$  (as opposed to ${\displaystyle C}$ ) is produced by \complement. (It corresponds to the Unicode symbol U+2201 ∁ COMPLEMENT.)

• Algebra of sets – Identities and relationships involving sets
• Intersection (set theory) – Set of elements common to all of some sets
• List of set identities and relations – Equalities for combinations of sets
• Naive set theory – Informal set theories
• Symmetric difference – Elements in exactly one of two sets
• Union (set theory) – Set of elements in any of some sets

• Bourbaki, N. (1970). Théorie des ensembles (in French). Paris: Hermann. ISBN 978-3-540-34034-8.
• Devlin, Keith J. (1979). Fundamentals of contemporary set theory. Universitext. Springer. ISBN 0-387-90441-7. Zbl 0407.04003.
• Halmos, Paul R. (1960). Naive set theory. The University Series in Undergraduate Mathematics. van Nostrand Company. ISBN 9780442030643. Zbl 0087.04403.

• Weisstein, Eric W. "Complement". MathWorld.
• Weisstein, Eric W. "Complement Set". MathWorld.