f(x1,...,xn)
f(x1,...,xj,...,xi,...,xn)=-f(x1,...,xi,...,xj,...,xn).
f\left(x\sigma(1),...,x\sigma(n)\right)=sgn(\sigma)f(x1,...,xn).
More generally, a polynomial
f(x1,...,xn,y1,...,yt)
x1,...,xn
xi
yj
Products of symmetric and alternating polynomials (in the same variables
x1,...,xn
This is exactly the addition table for parity, with "symmetric" corresponding to "even" and "alternating" corresponding to "odd". Thus, the direct sum of the spaces of symmetric and alternating polynomials forms a superalgebra (a
Z2
In particular, alternating polynomials form a module over the algebra of symmetric polynomials (the odd part of a superalgebra is a module over the even part); in fact it is a free module of rank 1, with the Vandermonde polynomial in n variables as generator.
If the characteristic of the coefficient ring is 2, there is no difference between the two concepts: the alternating polynomials are precisely the symmetric polynomials.
See main article: Vandermonde polynomial.
The basic alternating polynomial is the Vandermonde polynomial:
vn=\prod1\le(xj-xi).
The alternating polynomials are exactly the Vandermonde polynomial times a symmetric polynomial:
a=vn ⋅ s
s
vn
(xj-xi)
xi=xj
f(x1,...,xi,...,xj,...,xn)=f(x1,...,xj,...,xi,...,xn)=-f(x1,...,xi,...,xj,...,xn),
so
(xj-xi)
vn
vn
Conversely, the ratio of two alternating polynomials is a symmetric function, possibly rational (not necessarily a polynomial), though the ratio of an alternating polynomial over the Vandermonde polynomial is a polynomial.Schur polynomials are defined in this way, as an alternating polynomial divided by the Vandermonde polynomial.
Thus, denoting the ring of symmetric polynomials by Λn, the ring of symmetric and alternating polynomials is
Λn[vn]
Λn[vn]/\langle
| 2-\Delta\rangle | |
| v | |
| n |
| 2 | |
| \Delta=v | |
| n |
That is, the ring of symmetric and alternating polynomials is a quadratic extension of the ring of symmetric polynomials, where one has adjoined a square root of the discriminant.
Alternatively, it is:
R[e1,...,en,vn]/\langle
| 2-\Delta\rangle. | |
| v | |
| n |
If 2 is not invertible, the situation is somewhat different, and one must use a different polynomial
Wn
From the perspective of representation theory, the symmetric and alternating polynomials are subrepresentations of the action of the symmetric group on n letters on the polynomial ring in n variables. (Formally, the symmetric group acts on n letters, and thus acts on derived objects, particularly free objects on n letters, such as the ring of polynomials.)
The symmetric group has two 1-dimensional representations: the trivial representation and the sign representation. The symmetric polynomials are the trivial representation, and the alternating polynomials are the sign representation. Formally, the scalar span of any symmetric (resp., alternating) polynomial is a trivial (resp., sign) representation of the symmetric group, and multiplying the polynomials tensors the representations.
In characteristic 2, these are not distinct representations, and the analysis is more complicated.
If
n>2
Alternating polynomials are an unstable phenomenon: the ring of symmetric polynomials in n variables can be obtained from the ring of symmetric polynomials in arbitrarily many variables by evaluating all variables above
xn
n=3
x1
x2
(x2-x1)
(x1-x2)=-(x2-x1)
(x3-x1)
(x3-x2)