Relation (mathematics)

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Illustration of an example relation on a set A = { a, b, c, d }. An arrow from x to y indicates that the relation holds between x and y. The relation is represented by the set { (a,a), (a,b), (a,d), (b,a), (b,d), (c,b), (d,c), (d,d) } of ordered pairs.

In mathematics, a binary relation on a set may, or may not, hold between two given set members. For example, "is less than" is a relation on the set of natural numbers; it holds e.g. between 1 and 3 (denoted as 1<3) , and likewise between 3 and 4 (denoted as 3<4), but neither between 3 and 1 nor between 4 and 4. As another example, "is sister of" is a relation on the set of all people, it holds e.g. between Marie Curie and Bronisława Dłuska, and likewise vice versa. Set members may not be in relation "to a certain degree" - either they are in relation or they are not.

Formally, a relation R over a set X can be seen as a set of ordered pairs (x, y) of members of X.[1] The relation R holds between x and y if (x, y) is a member of R. For example, the relation "is less than" on the natural numbers is an infinite set Rless of pairs of natural numbers that contains both (1,3) and (3,4), but neither (3,1) nor (4,4). The relation "is a nontrivial divisor of" on the set of one-digit natural numbers is sufficiently small to be shown here: Rdiv = { (2,4), (2,6), (2,8), (3,6), (3,9), (4,8) }; for example 2 is a nontrivial divisor of 8, but not vice versa, hence (2,8) ∈ Rdiv, but (8,2) ∉ Rdiv.

If R is a relation that holds for x and y one often writes xRy. For most common relations in mathematics, special symbols are introduced, like "<" for "is less than", and "|" for "is a nontrivial divisor of", and, most popular "=" for "is equal to". For example, "1<3", "1 is less than 3", and "(1,3) ∈ Rless" mean all the same; some authors also write "(1,3) ∈ (<)".

Various properties of relations are investigated. A relation R is reflexive if xRx holds for all x, and irreflexive if xRx holds for no x. It is symmetric if xRy always implies yRx, and asymmetric if xRy implies that yRx is impossible. It is transitive if xRy and yRz always implies xRz. For example, "is less than" is irreflexive, asymmetric, and transitive, but neither reflexive nor symmetric, "is sister of" is transitive, but neither reflexive (e.g. Pierre Curie is not a sister of himself), nor symmetric, nor asymmetric, while being irreflexive or not may be a matter of definition (is every woman a sister of herself?), "is ancestor of" is transitive, while "is parent of" is not. Mathematical theorems are known about combinations of relation properties, such as "A transitive relation is irreflexive if, and only if, it is asymmetric".

Of particular importance are relations that satisfy certain combinations of properties. A partial order is a relation that is reflexive, antisymmetric, and transitive,[2] an equivalence relation is a relation that is reflexive, symmetric, and transitive,[3] a function is a relation that is right-unique and left-total (see below).[4][5]

Since relations are sets, they can be manipulated using set operations, including union, intersection, and complementation, and satisfying the laws of an algebra of sets. Beyond that, operations like the converse of a relation and the composition of relations are available, satisfying the laws of a calculus of relations.[6][7][8]

The above concept of relation[note 1] has been generalized to admit relations between members of two different sets (heterogeneous relation, like "lies on" between the set of all points and that of all lines in geometry), relations between three or more sets (Finitary relation, like "person x lives in town y at time z"), and relations between classes[note 2] (like "is an element of" on the class of all sets, see Binary relation § Sets versus classes).

Definition

Given a set X, a relation R over X is a set of ordered pairs of elements from X, formally: R ⊆ {(x,y): x,y ∈ X}.[1][9]

The statement (x, y) ∈ R reads "x is R-related to y" and is written in infix notation as xRy.[6][7] The order of the elements is important; if xy then yRx can be true or false independently of xRy. For example, 3 divides 9, but 9 does not divide 3.

Representation of relations

Representation as Hasse diagram (black lines) and directed graph (all lines)
y
x
1 2 3 4 6 12
1 No Yes Yes Yes Yes Yes
2 No No No Yes Yes Yes
3 No No No No Yes Yes
4 No No No No No Yes
6 No No No No No Yes
12 No No No No No No
Representation as boolean matrix

A relation on a finite set may be represented as:

For example, on the set of all divisors of 12, define the relation Rdiv by

x Rdiv y if x is a divisor of y and xy.

Formally, X = { 1, 2, 3, 4, 6, 12 } and Rdiv = { (1,2), (1,3), (1,4), (1,6), (1,12), (2,4), (2,6), (2,12), (3,6), (3,12), (4,12), (6,12) }. The representation of Rdiv as a boolean matrix is shown in the left table; the representation both as a Hasse diagram and as a directed graph is shown in the right picture.

The following are equivalent:

  • x Rdiv y is true.
  • (x,y) ∈ Rdiv.
  • A path from x to y exists in the Hasse diagram representing Rdiv.
  • An edge from x to y exists in the directed graph representing Rdiv.
  • In the boolean matrix representing Rdiv, the element in line x, column y is "".

Properties of relations

Some important properties that a relation R over a set X may have are:

Reflexive
for all xX, xRx. For example, ≥ is a reflexive relation but > is not.
Irreflexive (or strict)
for all xX, not xRx. For example, > is an irreflexive relation, but ≥ is not.

The previous 2 alternatives are not exhaustive; e.g., the red binary relation y = x2 given in the diagram below is neither irreflexive, nor reflexive, since it contains the pair (0, 0), but not (2, 2), respectively.

Symmetric
for all x, yX, if xRy then yRx. For example, "is a blood relative of" is a symmetric relation, because x is a blood relative of y if and only if y is a blood relative of x.
Antisymmetric
for all x, yX, if xRy and yRx then x = y. For example, ≥ is an antisymmetric relation; so is >, but vacuously (the condition in the definition is always false).[10]
Asymmetric
for all x, yX, if xRy then not yRx. A relation is asymmetric if and only if it is both antisymmetric and irreflexive.[11] For example, > is an asymmetric relation, but ≥ is not.

Again, the previous 3 alternatives are far from being exhaustive; as an example over the natural numbers, the relation xRy defined by x > 2 is neither symmetric (e.g. 5R1, but not 1R5) nor antisymmetric (e.g. 6R4, but also 4R6), let alone asymmetric.

Transitive
for all x, y, zX, if xRy and yRz then xRz. A transitive relation is irreflexive if and only if it is asymmetric.[12] For example, "is ancestor of" is a transitive relation, while "is parent of" is not.
Connected
for all x, yX, if xy then xRy or yRx. For example, on the natural numbers, < is connected, while "is a divisor of" is not (e.g. neither 5R7 nor 7R5).
Strongly connected
for all x, yX, xRy or yRx. For example, on the natural numbers, ≤ is strongly connected, but < is not. A relation is strongly connected if, and only if, it is connected and reflexive.
Examples of four types of binary relations over the real numbers: one-to-one (in green), one-to-many (in blue), many-to-one (in red), many-to-many (in black).

Uniqueness properties:

Injective[note 3] (also called left-unique)[13]
For all x, y, zX, if xRy and zRy then x = z. For example, the green and blue binary relations in the diagram are injective, but the red one is not (as it relates both −1 and 1 to 1), nor is the black one (as it relates both −1 and 1 to 0).
Functional[note 3] (also called right-unique,[13] right-definite[14] or univalent)[8]
For all x, y, zX, if xRy and xRz then y = z. Such a binary relation is called a partial function. For example, the red and green binary relations in the diagram are functional, but the blue one is not (as it relates 1 to both −1 and 1), nor is the black one (as it relates 0 to both −1 and 1).

Totality properties:

Serial[note 3] (also called total or left-total)
For all xX, there exists some yX such that xRy. Such a relation is called a multivalued function. For example, the red and green binary relations in the diagram are total, but the blue one is not (as it does not relate −1 to any real number), nor is the black one (as it does not relate 2 to any real number). As another example, > is a serial relation over the integers. But it is not a serial relation over the positive integers, because there is no y in the positive integers such that 1 > y.[15] However, < is a serial relation over the positive integers, the rational numbers and the real numbers. Every reflexive relation is serial: for a given x, choose y = x.
Surjective[note 3] (also called right-total[13] or onto)
For all y in X, there exists an x in X such that xRy. For example, the green and blue binary relations in the diagram are surjective, but the red one is not (as it does not relate any real number to −1), nor is the black one (as it does not relate any real number to 2).

Combinations of properties

Relations by property
Example
Partial order Refl Antisym Yes Subset
Strict partial order Irrefl Asym Yes Strict subset
Total order Refl Antisym Yes Yes Alphabetical order
Strict total order Irrefl Asym Yes Yes Strict alphabetical order
Equivalence relation Refl Sym Yes Equality

Relations that satisfy certain combinations of the above properties are particularly useful, and thus have received names by their own.

Equivalence relation
A relation that is reflexive, symmetric, and transitive. It is also a relation that is symmetric, transitive, and serial, since these properties imply reflexivity.

Orderings:

Partial order
A relation that is reflexive, antisymmetric, and transitive.
Strict partial order
A relation that is irreflexive, antisymmetric, and transitive.
Total order
A relation that is reflexive, antisymmetric, transitive and connected.[16]
Strict total order
A relation that is irreflexive, antisymmetric, transitive and connected.

Uniqueness properties:

One-to-one[note 3]
Injective and functional. For example, the green binary relation in the diagram is one-to-one, but the red, blue and black ones are not.
One-to-many[note 3]
Injective and not functional. For example, the blue binary relation in the diagram is one-to-many, but the red, green and black ones are not.
Many-to-one[note 3]
Functional and not injective. For example, the red binary relation in the diagram is many-to-one, but the green, blue and black ones are not.
Many-to-many[note 3]
Not injective nor functional. For example, the black binary relation in the diagram is many-to-many, but the red, green and blue ones are not.

Uniqueness and totality properties:

A function[note 3]
A binary relation that is functional and total. For example, the red and green binary relations in the diagram are functions, but the blue and black ones are not.
An injection[note 3]
A function that is injective. For example, the green binary relation in the diagram is an injection, but the red, blue and black ones are not.
A surjection[note 3]
A function that is surjective. For example, the green binary relation in the diagram is a surjection, but the red, blue and black ones are not.
A bijection[note 3]
A function that is injective and surjective. For example, the green binary relation in the diagram is a bijection, but the red, blue and black ones are not.

Operations on relations

Union[note 4]
If R and S are relations over X then RS = {(x, y) | xRy or xSy} is the union relation of R and S. The identity element of this operation is the empty relation. For example, ≤ is the union of < and =, and ≥ is the union of > and =.
Intersection[note 4]
If R and S are binary relations over X then RS = {(x, y) | xRy and xSy} is the intersection relation of R and S. The identity element of this operation is the universal relation. For example, "is a lower card of the same suit as" is the intersection of "is a lower card than" and "belongs to the same suit as".
Composition[note 4]
If R and S are binary relations over X then SR = {(x, z) | there exists yX such that xRy and ySz} (also denoted by R; S) is the composition relation of R and S. The identity element is the identity relation. The order of R and S in the notation SR, used here agrees with the standard notational order for composition of functions. For example, the composition "is mother of" ∘ "is parent of" yields "is maternal grandparent of", while the composition "is parent of" ∘ "is mother of" yields "is grandmother of". For the former case, if x is the parent of y and y is the mother of z, then x is the maternal grandparent of z.
Converse[note 4]
If R is a binary relation over sets X and Y then RT = {(y, x) | xRy} is the converse relation of R over Y and X. For example, = is the converse of itself, as is ≠, and < and > are each other's converse, as are ≤ and ≥. A binary relation is equal to its converse if and only if it is symmetric.
Complement[note 4]
If R is a binary relation over X then R = {(x, y) | x, yX and not xRy} (also denoted by R or ¬ R) is the complementary relation of R. For example, = and ≠ are each other's complement, as are ⊆ and ⊈, ⊇ and ⊉, and ∈ and ∉, and, for total orders, also < and ≥, and > and ≤. The complement of the converse relation RT is the converse of the complement:
Restriction[note 4]
If R is a relation over X and S is a subset of X then R|S = {(x, y) | xRy and x, yS} is the restriction relation of R to S. The expression R|S = {(x, y) | xRy and xS} is the left-restriction relation of R to S; the expression R|S = {(x, y) | xRy and yS} is called the right-restriction relation of R to S. If a relation is reflexive, irreflexive, symmetric, antisymmetric, asymmetric, transitive, total, trichotomous, a partial order, total order, strict weak order, total preorder (weak order), or an equivalence relation, then so too are its restrictions. However, the transitive closure of a restriction is a subset of the restriction of the transitive closure, i.e., in general not equal. For example, restricting the relation "x is parent of y" to females yields the relation "x is mother of the woman y"; its transitive closure does not relate a woman with her paternal grandmother. On the other hand, the transitive closure of "is parent of" is "is ancestor of"; its restriction to females does relate a woman with her paternal grandmother.

A binary relation R over sets X and Y is said to be contained in a relation S over X and Y, written if R is a subset of S, that is, for all and if xRy, then xSy. If R is contained in S and S is contained in R, then R and S are called equal written R = S. If R is contained in S but S is not contained in R, then R is said to be smaller than S, written RS. For example, on the rational numbers, the relation > is smaller than ≥, and equal to the composition > ∘ >.

Examples

Generalizations

The above concept of relation has been generalized to admit relations between members of two different sets. Given sets X and Y, a heterogeneous relation R over X and Y is a subset of { (x,y): xX, yY}.[1][17] When X = Y, the relation concept described above is obtained; it is often called homogeneous relation (or endorelation)[18][19] to distinguish it from its generalization. The above properties and operations that are marked "[note 3]" and "[note 4]", respectively, generalize to heterogeneous relations. An example of a heterogeneous relation is "ocean x borders continent y". The best-known examples are functions[note 5] with distinct domains and ranges, such as

See also

Notes

  1. ^ called "homogeneous binary relation (on sets)" when delineation from its generalizations is important
  2. ^ a generalization of sets
  3. ^ a b c d e f g h i j k l m These properties also generalize to heterogeneous relations.
  4. ^ a b c d e f g This operation also generalizes to heterogeneous relations.
  5. ^ that is, right-unique and left-total heterogeneous relations

References

  1. ^ a b c Codd, Edgar Frank (June 1970). "A Relational Model of Data for Large Shared Data Banks" (PDF). Communications of the ACM. 13 (6): 377–387. doi:10.1145/362384.362685. S2CID 207549016. Retrieved 2020-04-29.
  2. ^ Paul R. Halmos (1968). Naive Set Theory. Princeton: Nostrand. Chapter 14
  3. ^ Halmos (1968), Chapter 7
  4. ^ "Relation definition – Math Insight". mathinsight.org. Retrieved 2019-12-11.
  5. ^ Halmos (1968), Chapter 8
  6. ^ a b Ernst Schröder (1895) Algebra und Logic der Relative, via Internet Archive
  7. ^ a b C. I. Lewis (1918) A Survey of Symbolic Logic , pages 269 to 279, via internet Archive
  8. ^ a b Gunther Schmidt, 2010. Relational Mathematics. Cambridge University Press, ISBN 978-0-521-76268-7, Chapt. 5
  9. ^ Enderton 1977, Ch 3. pg. 40
  10. ^ Smith, Douglas; Eggen, Maurice; St. Andre, Richard (2006), A Transition to Advanced Mathematics (6th ed.), Brooks/Cole, p. 160, ISBN 0-534-39900-2
  11. ^ Nievergelt, Yves (2002), Foundations of Logic and Mathematics: Applications to Computer Science and Cryptography, Springer-Verlag, p. 158.
  12. ^ Flaška, V.; Ježek, J.; Kepka, T.; Kortelainen, J. (2007). Transitive Closures of Binary Relations I (PDF). Prague: School of Mathematics – Physics Charles University. p. 1. Archived from the original (PDF) on 2013-11-02. Lemma 1.1 (iv). This source refers to asymmetric relations as "strictly antisymmetric".
  13. ^ a b c Kilp, Knauer and Mikhalev: p. 3. The same four definitions appear in the following:
    • Peter J. Pahl; Rudolf Damrath (2001). Mathematical Foundations of Computational Engineering: A Handbook. Springer Science & Business Media. p. 506. ISBN 978-3-540-67995-0.
    • Eike Best (1996). Semantics of Sequential and Parallel Programs. Prentice Hall. pp. 19–21. ISBN 978-0-13-460643-9.
    • Robert-Christoph Riemann (1999). Modelling of Concurrent Systems: Structural and Semantical Methods in the High Level Petri Net Calculus. Herbert Utz Verlag. pp. 21–22. ISBN 978-3-89675-629-9.
  14. ^ Mäs, Stephan (2007), "Reasoning on Spatial Semantic Integrity Constraints", Spatial Information Theory: 8th International Conference, COSIT 2007, Melbourne, Australia, September 19–23, 2007, Proceedings, Lecture Notes in Computer Science, vol. 4736, Springer, pp. 285–302, doi:10.1007/978-3-540-74788-8_18
  15. ^ Yao, Y.Y.; Wong, S.K.M. (1995). "Generalization of rough sets using relationships between attribute values" (PDF). Proceedings of the 2nd Annual Joint Conference on Information Sciences: 30–33..
  16. ^ Joseph G. Rosenstein, Linear orderings, Academic Press, 1982, ISBN 0-12-597680-1, p. 4
  17. ^ Enderton 1977, Ch 3. pg. 40
  18. ^ M. E. Müller (2012). Relational Knowledge Discovery. Cambridge University Press. p. 22. ISBN 978-0-521-19021-3.
  19. ^ Peter J. Pahl; Rudolf Damrath (2001). Mathematical Foundations of Computational Engineering: A Handbook. Springer Science & Business Media. p. 496. ISBN 978-3-540-67995-0.

Bibliography