Antiisomorphism - Alchetron, The Free Social Encyclopedia

In Category theory, a branch of formal mathematics, an antiisomorphism (or anti-isomorphism) between structured sets A and B is an isomorphism from A to the opposite of B (or equivalently from the opposite of A to B). If there exists an antiisomorphism between two structures, they are said to be antiisomorphic.

Simple example

Let A be the binary relation (or directed graph) consisting of elements {1,2,3} and binary relation → defined as follows:

1 → 2 ;

1 → 3 ;

2 → 1.

Let B be the binary relation set consisting of elements {a,b,c} and binary relation ⇒ defined as follows:

b ⇒ a ;

c ⇒ a ;

a ⇒ b .

Note that the opposite of B (denoted B^op) is the same set of elements with the opposite binary relation ⇐ (that is, reverse all the arcs of the directed graph):

b ⇐ a ;

c ⇐ a ;

a ⇐ b .

If we replace a, b, and c with 1, 2, and 3 respectively, we will see that each rule in B^op is the same as some rule in A. That is, we can define an isomorphism ϕ from A to B^op by

ϕ ( n ) = { a if n = 1 ; b if n = 2 ; c if n = 3.

This ϕ is an antiisomorphism between A and B.

Ring anti-isomorphisms

Specializing the general language of category theory to the algebraic topic of rings, we have: Let R and S be rings and f: R → S a bijection between them, then if

f ( x + R y ) = f ( x ) + S f ( y ) and f ( x ⋅ R y ) = f ( y ) ⋅ S f ( x ) for all x , y ∈ R

f will be called a ring anti-isomorphism. If R = S then f will be called a ring anti-automorphism.

An example of a ring anti-automorphism is given by the conjugate mapping of quaternions:

x 0 + x 1 i + x 2 j + x 3 k ↦ x 0 − x 1 i − x 2 j − x 3 k .

References

Antiisomorphism Wikipedia

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Contents

Simple example

Ring anti-isomorphisms

References