In the mathematical field of abstract algebra, isotopy is an equivalence relation used to classify the algebraic notion of loop.
Isotopy for loops and quasigroups was introduced by, based on his slightly earlier definition of isotopy for algebras, which was in turn inspired by work of Steenrod.
Each quasigroup is isotopic to a loop.
Let
(Q, ⋅ )
(P,\circ)
\alpha(x)\circ\beta(y)=\gamma(x ⋅ y)
An isotopy is a homotopy for which each of the three maps is a bijection. Two quasigroups are isotopic if there is an isotopy between them. In terms of Latin squares, an isotopy is given by a permutation of rows α, a permutation of columns β, and a permutation on the underlying element set γ.
An autotopy is an isotopy from a quasigroup
(Q, ⋅ )
A principal isotopy is an isotopy for which γ is the identity map on Q. In this case the underlying sets of the quasigroups must be the same but the multiplications may differ.
Let
(L, ⋅ )
(K,\circ)
(\alpha,\beta,\gamma):L\toK
(\alpha0,\beta0,id)
(L, ⋅ )
(L,*)
\gamma
(L,*)
(K,\circ)
| -1 | |
| \alpha | |
| 0=\gamma |
\alpha
| -1 | |
| \beta | |
| 0=\gamma |
\beta
*
x*y=\alpha-1\gamma(x) ⋅ \beta-1\gamma(y)
Let
(L, ⋅ )
(L,\circ)
(L, ⋅ )
(\alpha,\beta,id)
(L, ⋅ )
(L,\circ)
| -1 | |
| \alpha=R | |
| b |
| -1 | |
| \beta=L | |
| a |
a=\alpha(e)
b=\beta(e)
A loop L is a G-loop if it is isomorphic to all its loop isotopes.
Let L be a loop and c an element of L. A bijection α of L is called a right pseudo-automorphism of L with companion element c if for all x, y the identity
\alpha(xy)c=\alpha(x)(\alpha(y)c)
We say that a loop property P is universal if it is isotopy invariant, that is, P holds for a loop L if and only if P holds for all loop isotopes of L. Clearly, it is enough to check if P holds for all principal isotopes of L.
For example, since the isotopes of a commutative loop need not be commutative, commutativity is not universal. However, associativity and being an abelian group are universal properties. In fact, every group is a G-loop.
Given a loop L, one can define an incidence geometric structure called a 3-net. Conversely, after fixing an origin and an order of the line classes, a 3-net gives rise to a loop. Choosing a different origin or exchanging the line classes may result in nonisomorphic coordinate loops. However, the coordinate loops are always isotopic. In other words, two loops are isotopic if and only if they are equivalent from geometric point of view.
The dictionary between algebraic and geometric concepts is as follows