Antihomomorphism

Last updated April 30, 2024

In mathematics, an antihomomorphism is a type of function defined on sets with multiplication that reverses the order of multiplication. An antiautomorphism is an invertible antihomomorphism, i.e. an antiisomorphism, from a set to itself. From bijectivity it follows that antiautomorphisms have inverses, and that the inverse of an antiautomorphism is also an antiautomorphism.

Definition

Informally, an antihomomorphism is a map that switches the order of multiplication. Formally, an antihomomorphism between structures $X$ and $Y$ is a homomorphism $\phi \colon X\to Y^{\text{op}}$ , where $Y^{\text{op}}$ equals $Y$ as a set, but has its multiplication reversed to that defined on $Y$ . Denoting the (generally non-commutative) multiplication on $Y$ by $\cdot$ , the multiplication on $Y^{\text{op}}$ , denoted by $*$ , is defined by $x*y:=y\cdot x$ . The object $Y^{\text{op}}$ is called the opposite object to $Y$ (respectively, opposite group , opposite algebra , opposite category etc.).

This definition is equivalent to that of a homomorphism $\phi \colon X^{\text{op}}\to Y$ (reversing the operation before or after applying the map is equivalent). Formally, sending $X$ to $X^{\text{op}}$ and acting as the identity on maps is a functor (indeed, an involution).

Examples

In group theory, an antihomomorphism is a map between two groups that reverses the order of multiplication. So if φ : X → Y is a group antihomomorphism,

φ(xy) = φ(y)φ(x)

for all x, y in X.

The map that sends x to x⁻¹ is an example of a group antiautomorphism. Another important example is the transpose operation in linear algebra, which takes row vectors to column vectors. Any vector-matrix equation may be transposed to an equivalent equation where the order of the factors is reversed.

With matrices, an example of an antiautomorphism is given by the transpose map. Since inversion and transposing both give antiautomorphisms, their composition is an automorphism. This involution is often called the contragredient map, and it provides an example of an outer automorphism of the general linear group GL(n, F), where F is a field, except when |F| = 2 and n = 1 or 2, or |F| = 3 and n = 1 (i.e., for the groups GL(1, 2), GL(2, 2), and GL(1, 3)).

In ring theory, an antihomomorphism is a map between two rings that preserves addition, but reverses the order of multiplication. So φ : X → Y is a ring antihomomorphism if and only if:

φ(1) = 1

φ(x + y) = φ(x) + φ(y)

φ(xy) = φ(y)φ(x)

for all x, y in X.^[1]

For algebras over a field K, φ must be a K-linear map of the underlying vector space. If the underlying field has an involution, one can instead ask φ to be conjugate-linear, as in conjugate transpose, below.

Involutions

It is frequently the case that antiautomorphisms are involutions, i.e. the square of the antiautomorphism is the identity map; these are also called involutive antiautomorphisms. For example, in any group the map that sends x to its inverse x⁻¹ is an involutive antiautomorphism.

A ring with an involutive antiautomorphism is called a *-ring, and these form an important class of examples.

Properties

If the source X or the target Y is commutative, then an antihomomorphism is the same thing as a homomorphism.

The composition of two antihomomorphisms is always a homomorphism, since reversing the order twice preserves order. The composition of an antihomomorphism with a homomorphism gives another antihomomorphism.

Related Research Articles

<span class="mw-page-title-main">Automorphism</span> Isomorphism of an object to itself

In mathematics, an automorphism is an isomorphism from a mathematical object to itself. It is, in some sense, a symmetry of the object, and a way of mapping the object to itself while preserving all of its structure. The set of all automorphisms of an object forms a group, called the automorphism group. It is, loosely speaking, the symmetry group of the object.

In mathematics, an associative algebraA over a commutative ring K is a ring A together with a ring homomorphism from K into the center of A. This is thus an algebraic structure with an addition, a multiplication, and a scalar multiplication. The addition and multiplication operations together give A the structure of a ring; the addition and scalar multiplication operations together give A the structure of a module or vector space over K. In this article we will also use the term K-algebra to mean an associative algebra over K. A standard first example of a K-algebra is a ring of square matrices over a commutative ring K, with the usual matrix multiplication.

In mathematics, specifically category theory, a functor is a mapping between categories. Functors were first considered in algebraic topology, where algebraic objects are associated to topological spaces, and maps between these algebraic objects are associated to continuous maps between spaces. Nowadays, functors are used throughout modern mathematics to relate various categories. Thus, functors are important in all areas within mathematics to which category theory is applied.

In algebra, a homomorphism is a structure-preserving map between two algebraic structures of the same type. The word homomorphism comes from the Ancient Greek language: ὁμός meaning "same" and μορφή meaning "form" or "shape". However, the word was apparently introduced to mathematics due to a (mis)translation of German ähnlich meaning "similar" to ὁμός meaning "same". The term "homomorphism" appeared as early as 1892, when it was attributed to the German mathematician Felix Klein (1849–1925).

<span class="mw-page-title-main">Isomorphism</span> In mathematics, invertible homomorphism

In mathematics, an isomorphism is a structure-preserving mapping between two structures of the same type that can be reversed by an inverse mapping. Two mathematical structures are isomorphic if an isomorphism exists between them. The word isomorphism is derived from the Ancient Greek: ἴσοςisos "equal", and μορφήmorphe "form" or "shape".

<span class="mw-page-title-main">Lie group</span> Group that is also a differentiable manifold with group operations that are smooth

In mathematics, a Lie group is a group that is also a differentiable manifold, such that group multiplication and taking inverses are both differentiable.

In category theory, a branch of mathematics, a natural transformation provides a way of transforming one functor into another while respecting the internal structure of the categories involved. Hence, a natural transformation can be considered to be a "morphism of functors". Informally, the notion of a natural transformation states that a particular map between functors can be done consistently over an entire category.

In mathematics, the complex conjugate of a complex number is the number with an equal real part and an imaginary part equal in magnitude but opposite in sign. That is, if $and are real numbers then the complex conjugate of is The complex conjugate of is often denoted as or .$

In mathematics, and more specifically in abstract algebra, a *-algebra is a mathematical structure consisting of two involutive rings $R$ and $A$ , where $R$ is commutative and $A$ has the structure of an associative algebra over $R$ . Involutive algebras generalize the idea of a number system equipped with conjugation, for example the complex numbers and complex conjugation, matrices over the complex numbers and conjugate transpose, and linear operators over a Hilbert space and Hermitian adjoints. However, it may happen that an algebra admits no involution.

<span class="mw-page-title-main">Involution (mathematics)</span> Function that is its own inverse

In mathematics, an involution, involutory function, or self-inverse function is a function $f$ that is its own inverse,

In mathematics, a Hopf algebra, named after Heinz Hopf, is a structure that is simultaneously an algebra and a coalgebra, with these structures' compatibility making it a bialgebra, and that moreover is equipped with an antihomomorphism satisfying a certain property. The representation theory of a Hopf algebra is particularly nice, since the existence of compatible comultiplication, counit, and antipode allows for the construction of tensor products of representations, trivial representations, and dual representations.

In mathematics and theoretical physics, a superalgebra is a Z₂-graded algebra. That is, it is an algebra over a commutative ring or field with a decomposition into "even" and "odd" pieces and a multiplication operator that respects the grading.

In algebra, a module homomorphism is a function between modules that preserves the module structures. Explicitly, if M and N are left modules over a ring R, then a function $is called an R - module homomorphism or an R - linear map if for any x, y in M and r in R,$

In mathematics, a duality translates concepts, theorems or mathematical structures into other concepts, theorems or structures in a one-to-one fashion, often by means of an involution operation: if the dual of $A$ is $B$ , then the dual of $B$ is $A$ . Such involutions sometimes have fixed points, so that the dual of $A$ is $A$ itself. For example, Desargues' theorem is self-dual in this sense under the standard duality in projective geometry.

In the theory of von Neumann algebras, a part of the mathematical field of functional analysis, Tomita–Takesaki theory is a method for constructing modular automorphisms of von Neumann algebras from the polar decomposition of a certain involution. It is essential for the theory of type III factors, and has led to a good structure theory for these previously intractable objects.

In mathematics, specifically abstract algebra, the opposite of a ring is another ring with the same elements and addition operation, but with the multiplication performed in the reverse order. More explicitly, the opposite of a ring (R, +, ⋅) is the ring (R, +, ∗) whose multiplication ∗ is defined by a ∗ b = b⋅a for all a, b in R. The opposite ring can be used to define multimodules, a generalization of bimodules. They also help clarify the relationship between left and right modules (see § Properties).

In mathematics, particularly in abstract algebra, a semigroup with involution or a *-semigroup is a semigroup equipped with an involutive anti-automorphism, which—roughly speaking—brings it closer to a group because this involution, considered as unary operator, exhibits certain fundamental properties of the operation of taking the inverse in a group:

In linear algebra, particularly projective geometry, a semilinear map between vector spaces V and W over a field K is a function that is a linear map "up to a twist", hence semi-linear, where "twist" means "field automorphism of K". Explicitly, it is a function T : V → W that is:

In mathematics, the automorphism group of an object X is the group consisting of automorphisms of X under composition of morphisms. For example, if X is a finite-dimensional vector space, then the automorphism group of X is the group of invertible linear transformations from X to itself. If instead X is a group, then its automorphism group $is the group consisting of all group automorphisms of X .$

This is a glossary for the terminology in a mathematical field of functional analysis.

References

↑ Jacobson, Nathan (1943). The Theory of Rings. Mathematical Surveys and Monographs. Vol. 2. American Mathematical Society. p. 16. ISBN 0821815024.

Weisstein, Eric W. "Antihomomorphism". MathWorld .

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Jacobson, Nathan (1943). The Theory of Rings. Mathematical Surveys and Monographs. Vol. 2. American Mathematical Society. p. 16. ISBN 0821815024.

[1]