Commutative property

Commutativity is a widely used mathematical term that refers to the ability to change the order of something without changing the end result. It is a fundamental property in most branches of mathematics and many proofs depend on it. The commutativity of simple operations was for many years implicitly assumed and the property was not given a name or attributed until the 19th century when mathematicians began to formalize the theory of mathematics.

Common uses

The commutative property (or commutative law) is a property associated with binary operations and functions. Similarly, if the commutative property holds for a pair of elements under a certain binary operation then it is said that the two elements commute under that operation.

In group and set theory, many algebraic structures are called commutative when certain operands satisfy the commutative property. In higher branches of math, such as analysis and linear algebra the commutativity of well known operations (such as addition and multiplication on real and complex numbers) is often used (or implicitly assumed) in proofs.^[1]^[2]

Mathematical definitions

A binary operation $\scriptstyle *$ on a set $\scriptstyle S$ is said to be commutative if:^[3]

x*y=y*x\quad \forall x,y\in S

An operation that does not satisfy the above property is called noncommutative.

It's said $\scriptstyle x$ commutes with $\scriptstyle y$ under $\scriptstyle *$ if:^[4]

x*y=y*x

A binary function $\scriptstyle f\colon A\times B\rightarrow C$ is said to be commutative if:

f(x,y)=f(y,x)\quad \forall x\in A,y\in B

History

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.^[5]^[6] Euclid is known to have assumed the commutative property of multiplication in his book Elements.^[7] Formal uses of the commutative property arose in the late 18th and early 19th century when mathematicians began to work on a theory of functions. Today the commutative property is a well known and basic property used in most branches of mathematics. Simple versions of the commutative property are usually taught in beginning mathematics courses.

The first use of the actual term commutative was in a memoir by Francois Servois in 1814,^[8]^[9] which used the word commutatives when describing functions that have what is now called the commutative property. The word is a combination of the French word commuter meaning "to substitute or switch" and the suffix -ative meaning "tending to" so the word literally means "tending to substitute or switch." The term then appeared in English in Philosophical Transactions of the Royal Society in 1844.^[8]

Related Properties

Associativity

The associative property is closely related to the commutative property. The associative property states that the order in which operations are performed doesn't affect the final result. In contrast, the commutative property states that the order of the terms doesn't affect the final result.

Symmetry

Symmetry can be directly linked to commutativity. When a commutative operator is written as a binary function then the resulting function is symmetric across the line $\scriptstyle y=x$ . As an example, if we let a function $\scriptstyle f$ represent addition (a commutative operation) so that $\scriptstyle f(x,y)=x+y$ then $\scriptstyle f$ is a symmetric function which can be seen in the image on the right.

Center

When an operation is noncommutative over some set it's still possible that some of the elements of the set commute with each other. The subset consisting of all these elements is often called the center.

Abelian

The term Abelian is sometimes associated with commutativity because of Abelian groups. These are groups which satisfy the commutative property, and they are often used in group theory. However, the word Abelian refers to something named after Niels Abel and can have nothing to do with commutativity. For example, Abelian integral.

Examples

Commutative operations in everyday life

Putting your shoes on resembles a commutative operation since it doesn't matter if you put the left or right shoe on first, the end result (having both shoes on), is the same.
When making change we take advantage of the commutativity of addition. It doesn't matter what order we put the change in, it always adds to the same total.

Commutative operations in math

Two well-known examples of commutative binary operations are:^[4]

The addition of real numbers, which is commutative since

y+z=z+y\quad \forall y,z\in \mathbb {R}

For example 4 + 5 = 5 + 4, since both expressions equal 9.

The multiplication of real numbers, which is commutative since

yz=zy\quad \forall y,z\in \mathbb {R}

For example, 3 × 5 = 5 × 3, since both expressions equal 15.

Further examples of commutative binary operations include addition and multiplication of complex numbers, addition of vectors, and intersection and union of sets.

Noncommutative operations in everyday life

Concatenation, the act of joining character strings together, is a noncommutative operation.

Washing and drying your clothes resembles a noncommutative operation, if you dry first and then wash, you get a significantly different result than if you wash first and then dry.
The Rubik's Cube is noncommutative. For example, twisting the front face clockwise, the top face clockwise and the front face counterclockwise (FUF') does not yield the same result as twisting the front face clockwise, then counterclockwise and finally twisting the top clockwise (FF'U). The twists don't commute. This is studied in group theory.

Noncommutative operations in math

Some noncommutative binary operations are:^[10]

subtraction $\scriptstyle a-b$
division $\scriptstyle a/b$
matrix multiplication, which is noncommutative since

{\begin{bmatrix}0&2\\0&1\end{bmatrix}}={\begin{bmatrix}1&1\\0&1\end{bmatrix}}\cdot {\begin{bmatrix}0&1\\0&1\end{bmatrix}}\neq {\begin{bmatrix}0&1\\0&1\end{bmatrix}}\cdot {\begin{bmatrix}1&1\\0&1\end{bmatrix}}={\begin{bmatrix}0&1\\0&1\end{bmatrix}}

Mathematical structures and commutativity

An abelian group is a group whose group operation is commutative.^[11]
A commutative ring is a ring whose multiplication is commutative. (Addition in a ring is always commutative.)^[12]
In a field both addition and multiplication are commutative.^[13]
The center is the largest commutative subset of a group.^[14]
A Lie algebra is said to be commutative if the commutator [A,B] is 0 for every A and B.^[15]

References

^ Axler, Sheldon (1997). Linear Algebra Done Right, 2e. Springer. ISBN 0-387-98258-2.The book defines the commutativity of addition and multiplication on pg 2, and then uses it implicitly throughout.
^ Gallian, Joseph (2006). Contemporary Abstract Algebra, 6e. ISBN 0-618-51471-6.Many of the proofs in this book implicitly use the commutative property
^ Krowne, Aaron, Commutative at PlanetMath., Accessed 8 August 2007.
^ ^a ^b Weisstein, Eric W. "Commutative". MathWorld., Accessed 8 August 2007.
^ http://www.ethnomath.org/resources/lumpkin1997.pdf Lumpkin, B. (1997). The Mathematical Legacy Of Ancient Egypt - A Response To Robert Palter. Unpublished manuscript.
^ Robins, R. Gay, and Charles C. D. Shute. 1987. The Rhind Mathematical Papyrus: An Ancient Egyptian Text. London: British Museum Publications Limited. ISBN 0-7141-0944-4
^ O'Conner, J J and Robertson, E F. MacTutor history of real numbers, Accessed 8 August 2007
^ ^a ^b Cabillón, Julio and Miller, Jeff. Earliest Known Uses Of Mathematical Terms, Accessed 8 August 2007
^ O'Conner, J J and Robertson, E F. MacTutor biography of François Servois, Accessed 8 August 2007
^ Yark. Examples of non-commutative operations at PlanetMath., Accessed 8 August 2007
^ Weisstein, Eric W. "Abelian Group". MathWorld., Accessed 8 August 2007
^ Weisstein, Eric W. "Commutative Ring". MathWorld., Accessed 8 August 2007
^ Weisstein, Eric W. "Field". MathWorld., Accessed 8 August 2007
^ Yark. Group Center at PlanetMath., Accessed 8 August 2007
^ Weisstein, Eric W. "Commutative Algebra". MathWorld., Accessed 8 August 2007