Commutative property

Commutative property
Type	Property
Field	Algebra
Statement	A binary operation is commutative if changing the order of the operands does not change the result.
Symbolic statement

In mathematics, a binary operation is commutative if changing the order of the operands does not change the result. It is a fundamental property of many binary operations, and many mathematical proofs depend on it. Perhaps most familiar as a property of arithmetic, e.g. "3 + 4 = 4 + 3" or "2 × 5 = 5 × 2", the property can also be used in more advanced settings. The name is needed because there are operations, such as division and subtraction, that do not have it (for example, "3 − 5 ≠ 5 − 3"); such operations are not commutative, and so are referred to as noncommutative operations.

The idea that simple operations, such as the multiplication and addition of numbers, are commutative was for many centuries implicitly assumed. Thus, this property was not named until the 19th century, when new algebraic structures started to be studied.^[1]

Definition

A binary operation $*$ on a set S is commutative if $x*y=y*x$ for all $x,y\in S$ .^[2] An operation that is not commutative is said to be noncommutative.^[3]

One says that $x$ commutes with $y$ or that $x$ and $y$ commute under $*$ if^[4] $x*y=y*x.$

So, an operation is commutative if every two elements commute.^[4] An operation is noncommutative if there are two elements such that $x*y\neq y*x.$ This does not exclude the possibility that some pairs of elements commute.^[3]

Examples

Commutative operations

Addition and multiplication are commutative in most number systems, and, in particular, between natural numbers, integers, rational numbers, real numbers and complex numbers. This is also true in every field.^[5]
Addition is commutative in every vector space and in every algebra.^[6]
Union and intersection are commutative operations on sets.^[7]
"And" and "or" are commutative logical operations.^[8]

Noncommutative operations

Division, subtraction, and exponentiation

Division is noncommutative, since $1\div 2\neq 2\div 1$ .^[9]

Subtraction is noncommutative, since $0-1\neq 1-0$ . However it is classified more precisely as anti-commutative, since $x-y=-(y-x)$ for every ⁠ $x$ ⁠ and ⁠ $y$ ⁠.^[9]

Exponentiation is noncommutative, since $2^{3}\neq 3^{2}$ .^[9] See also Equation x^y = y^x.

Truth functions

Some truth functions are noncommutative, since their truth tables are different when one changes the order of the operands.^[10] For example, the truth tables for $(A \Rightarrow B) = (\negA \lor B)$ and $(B \Rightarrow A) = (A \lor \negB)$ are

$A$	$B$	$A \Rightarrow B$	$B \Rightarrow A$
F	F	T	T
F	T	T	F
T	F	F	T
T	T	T	T

Function composition

Function composition is generally noncommutative.^[11] For example, if $f(x)=2x+1$ and $g(x)=3x+7$ . Then $(f\circ g)(x)=f(g(x))=2(3x+7)+1=6x+15$ and $(g\circ f)(x)=g(f(x))=3(2x+1)+7=6x+10.$

Matrix multiplication

Matrix multiplication of square matrices of a given dimension is a noncommutative operation, except for ⁠ $1\times 1$ ⁠ matrices. For example:^[12] ${\begin{bmatrix}0&2\\0&1\end{bmatrix}}={\begin{bmatrix}1&1\\0&1\end{bmatrix}}{\begin{bmatrix}0&1\\0&1\end{bmatrix}}\neq {\begin{bmatrix}0&1\\0&1\end{bmatrix}}{\begin{bmatrix}1&1\\0&1\end{bmatrix}}={\begin{bmatrix}0&1\\0&1\end{bmatrix}}$

Vector product

The vector product (or cross product) of two vectors in three dimensions is anti-commutative; i.e., $\mathbf {b} \times \mathbf {a} =-(\mathbf {a} \times \mathbf {b} )$ .^[13]

Commutative structures

Some types of algebraic structures involve an operation that does not require commutativity. If this operation is commutative for a specific structure, the structure is often said to be commutative. So,

a commutative semigroup is a semigroup whose operation is commutative;^[14]
a commutative monoid is a monoid whose operation is commutative;^[15]
a commutative group or abelian group is a group whose operation is commutative;^[16]
a commutative ring is a ring whose multiplication is commutative. (Addition in a ring is always commutative.)^[17]

However, in the case of algebras, the phrase "commutative algebra" refers only to associative algebras that have a commutative multiplication.^[18]

History and etymology

Records of the implicit use of the commutative property go back to ancient times. The Egyptians used the commutative property of multiplication to simplify computing products.^[19] Euclid is known to have assumed the commutative property of multiplication in his book Elements.^[20] Formal uses of the commutative property arose in the late 18th and early 19th centuries when mathematicians began to work on a theory of functions. Nowadays, the commutative property is a well-known and basic property used in most branches of mathematics.^[2]

The first recorded use of the term commutative was in a memoir by François Servois in 1814, which used the word commutatives when describing functions that have what is now called the commutative property.^[21] Commutative is the feminine form of the French adjective commutatif, which is derived from the French noun commutation and the French verb commuter, meaning "to exchange" or "to switch", a cognate of to commute. The term then appeared in English in 1838. in Duncan Gregory's article entitled "On the real nature of symbolical algebra" published in 1840 in the Transactions of the Royal Society of Edinburgh.^[22]

Notes

^ Rice 2011, p. 4.
^ ^a ^b Saracino 2008, p. 11.
^ ^a ^b Hall 1966, pp. 262–263.
^ ^a ^b Lovett 2022, p. 12.
^ Rosen 2013, See the Appendix I.
^ Sterling 2009, p. 248.
^ Johnson 2003, p. 642.
^ O'Regan 2008, p. 33.
^ ^a ^b ^c Posamentier et al. 2013, p. 71.
^ Medina et al. 2004, p. 617.
^ Tarasov 2008, p. 56.
^ Cooke 2014, p. 7.
^ Haghighi, Kumar & Mishev 2024, p. 118.
^ Grillet 2001, pp. 1–2.
^ Grillet 2001, p. 3.
^ Gallian 2006, p. 34.
^ Gallian 2006, p. 236.
^ Tuset 2025, p. 99.
^ Gay & Shute 1987, p. 16‐17.
^ Barbeau 1968, p. 183. See Book VII, Proposition 5, in David E. Joyce's online edition of Euclid's Elements
^ Allaire & Bradley 2002.
^ Rice 2011, p. 4; Gregory 1840.

References

Allaire, Patricia R.; Bradley, Robert E. (2002). "Symbolical Algebra as a Foundation for Calculus: D. F. Gregory's Contribution". Historia Mathematica. 29: 395–426. doi:10.1006/hmat.2002.2358.
Barbeau, Alice Mae (1968). A Historical Approach to the Theory of Groups. Vol. 2. University of Wisconsin--Madison.
Cooke, Richard G. (2014). Infinite Matrices and Sequence Spaces. Dover Publications. ISBN 978-0-486-78083-2.
Gallian, Joseph (2006). Contemporary Abstract Algebra (6e ed.). Houghton Mifflin. ISBN 0-618-51471-6.
Gay, Robins R.; Shute, Charles C. D. (1987). The Rhind Mathematical Papyrus: An Ancient Egyptian Text. British Museum. ISBN 0-7141-0944-4.
Gregory, D. F. (1840). "On the real nature of symbolical algebra". Transactions of the Royal Society of Edinburgh. 14: 208–216.
Grillet, P. A. (2001). Commutative semigroups. Advances in Mathematics. Vol. 2. Dordrecht: Kluwer Academic Publishers. doi:10.1007/978-1-4757-3389-1. ISBN 0-7923-7067-8. MR 2017849.
Haghighi, Aliakbar Montazer; Kumar, Abburi Anil; Mishev, Dimitar (2024). Higher Mathematics for Science and Engineering. Springer.
Hall, F. M. (1966). An Introduction to Abstract Algebra, Volume 1. New York: Cambridge University Press. MR 0197233.
Johnson, James L. (2003). Probability and Statistics for Computer Science. John Wiley & Sons.
Lovett, Stephen (2022). Abstract Algebra: A First Course. CRC Press.
Medina, Jesús; Ojeda-Aciego, Manuel; Valverde, Agustín; Vojtáš, Peter (2004). "Towards Biresiduated Multi-adjoint Logic Programming". In Conejo, Ricardo; Urretavizcaya, Maite; Pérez-de-la-Cruz, José-Luis (eds.). Current Topics in Artificial Intelligence: 10th Conference of the Spanish Association for Artificial Intelligence, CAEPIA 2003, and 5th Conference on Technology Transfer, TTIA 2003, November 12-14, 2003. San Sebastian, Spain: Springer. doi:10.1007/b98369.
O'Regan, Gerard (2008). A brief history of computing. Springer. ISBN 978-1-84800-083-4.
Posamentier, Alfred S.; Farber, William; Germain-Williams, Terri L.; Paris, Elaine; Thaller, Bernd; Lehmann, Ingmar (2013). 100 Commonly Asked Questions in Math Class. Corwin Press. ISBN 978-1-4522-4308-5.
Rice, Adrian (2011). "Introduction". In Flood, Raymond; Rice, Adrian; Wilson, Robin (eds.). Mathematics in Victorian Britain. Oxford University Press. ISBN 9780191627941.
Rosen, Kenneth (2013). Discrete Maths and Its Applications Global Edition. McGraw Hill. ISBN 978-0-07-131501-2.
Saracino, Dan (2008). Abstract Algebra: A First Course (2nd ed.). Waveland Press Inc.
Sterling, Mary J. (2009). Linear Algebra For Dummies. John Wiley & Sons. ISBN 978-0-470-43090-3.
Tarasov, Vasily (2008). Quantum Mechanics of Non-Hamiltonian and Dissipative Systems. Vol. 7 (1st ed.). Elsevier.
Tuset, Lars (2025). Abstract Algebra via Numbers. Cham: Springer. doi:10.1007/978-3-031-74623-9. ISBN 978-3-031-74622-2. MR 4886847.