Alternatization

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In mathematics, more specifically in multilinear algebra, the notion of alternatization (or alternatisation in British English) is used to pass from any map to an alternating map.

An alternating map is a multilinear map (e.g., a bilinear map or a multilinear form) that is equal to zero for every tuple with two adjacent elements that are equal.

Definitions

Alternating map

Let S be a set, A be an abelian group, given a map \alpha: S \times S \to A, \alpha is said to be an alternating map if

\forall x \in S, \quad \alpha(x,x) = 0.

Alternating bilinear map

An alternating bilinear map is a bilinear map that is also an alternating map.

An alternating bilinear form is a special case of alternating bilinear map. As bilinear forms can be defined as maps between vector spaces or modules, we distinguish two cases.

Vector spaces
Let V be a vector space over a field K, and \alpha: V \times V \to K be a bilinear form. Then \alpha is said to be an alternating bilinear form if [1][2]
\forall x \in V, \quad \alpha(x,x) = 0.
Modules
Let M be a module over a ring R, and \alpha: M \times M \to R be a bilinear form. Then \alpha is said to be an alternating bilinear form if
\forall x \in M, \quad \alpha(x,x) = 0.

Alternating multilinear form

An alternating multilinear form generalizes the concept of alternating bilinear form to n dimensions. As multilinear forms can be defined as maps between vector spaces or modules, we distinguish two cases.

Vector spaces
Let V be a vector space over a field K, and \alpha: V \times V \times \ldots \times V \to K be a multilinear form. Then \alpha is said to be an alternating multilinear form if
\forall x_1,x_2,\ldots,x_n \in V, \quad \forall i \in \{1,2,\ldots,n-1\}, \quad x_i = x_{i+1} \, \implies \, \alpha(x_1,x_2,\ldots,x_n) = 0.
Modules
Let M be a module over a ring R, and \alpha: M \times M \times \ldots \times M \to R be a multilinear form. Then \alpha is said to be an alternating multilinear form if [3]
\forall x_1,x_2,\ldots,x_n \in M, \quad \forall i \in \{1,2,\ldots,n-1\}, \quad x_i = x_{i+1} \, \implies \, \alpha(x_1,x_2,\ldots,x_n) = 0.

Alternatization of a bilinear map

Let S be a set, A be an abelian group, and \alpha: S \times S \to A be a bilinear map. \forall x,y \in S, the alternatization of the map \alpha is the map

\beta: S \times S \to A
(x,y) \mapsto \alpha(x,y) - \alpha(y,x).

Example

Properties

\forall x,y \in S, \quad \alpha(x,y) + \alpha(y,x) = 0.
Proof for a bilinear form
\forall x,y \in V,
0 = \alpha(x+y,x+y)
   = \alpha(x,x+y) + \alpha(y,x+y)
   = \alpha(x,x) + \alpha(x,y) + \alpha(y,x) + \alpha(y,y)
   = \alpha(x,y) + \alpha(y,x)


  • If the characteristic of the ring R is not equal to 2, then every antisymmetric multilinear form is alternating.[5]
  • The alternatization of an alternating map is its double.
  • There may be non-bilinear maps whose alternatization is bilinear.

See also

Notes

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References

  • Rotman 1995, page 235.
  • Cohn 2003, page 298.
  • Lang 2002, page 511.
  • Rotman 1995, page 235.
  • Rotman 1995, page 235.
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