In mathematics, a symmetric polynomial is a polynomial in variables, such that if any of the variables are interchanged, one obtains the same polynomial. Formally, is a symmetric polynomial if for any permutation of the subscripts one has .
Symmetric polynomials arise naturally in the study of the relation between the roots of a polynomial in one variable and its coefficients, since the coefficients can be given by polynomial expressions in the roots, and all roots play a similar role in this setting. From this point of view the elementary symmetric polynomials are the most fundamental symmetric polynomials. Indeed, a theorem called the fundamental theorem of symmetric polynomials states that any symmetric polynomial can be expressed in terms of elementary symmetric polynomials. This implies that every symmetric polynomial expression in the roots of a monic polynomial can alternatively be given as a polynomial expression in the coefficients of the polynomial.
Symmetric polynomials also form an interesting structure by themselves, independently of any relation to the roots of a polynomial. In this context other collections of specific symmetric polynomials, such as complete homogeneous, power sum, and Schur polynomials play important roles alongside the elementary ones. The resulting structures, and in particular the ring of symmetric functions, are of great importance in combinatorics and in representation theory.
The following polynomials in two variables X1 and X2 are symmetric:
| 3+ | |
| X | |
| 1 |
| 3-7 | |
| X | |
| 2 |
4
| 2 | |
| X | |
| 2 |
| 3X | |
| +X | |
| 2 |
+X1X
| 3 | |
| 2 |
+(X1+X
| 4 | |
| 2) |
X1X2X3-2X1X2-2X1X3-2X2X3
\prod1\leq(Xi-X
| 2 | |
| j) |
On the other hand, the polynomial in two variables
X1-X2
X1
X2
X2-X1
| 2X | |
| X | |
| 3 |
+X1X
| 2 | |
| 3 |
+
| 2X | |
| X | |
| 2X |
| 4 | |
| 3 |
| 2X | |
| X | |
| 3 |
+X1X
| 2 | |
| 3 |
+
| 2X | |
| X | |
| 2X |
| 4 | |
| 3 |
+
| 4X | |
| X | |
| 2X |
| 2 | |
| 3 |
+X1X
| 4 | |
| 3 |
+
| 4X | |
| X | |
| 3 |
See main article: Galois theory. One context in which symmetric polynomial functions occur is in the study of monic univariate polynomials of degree n having n roots in a given field. These n roots determine the polynomial, and when they are considered as independent variables, the coefficients of the polynomial are symmetric polynomial functions of the roots. Moreover the fundamental theorem of symmetric polynomials implies that a polynomial function f of the n roots can be expressed as (another) polynomial function of the coefficients of the polynomial determined by the roots if and only if f is given by a symmetric polynomial.
This yields the approach to solving polynomial equations by inverting this map, "breaking" the symmetry – given the coefficients of the polynomial (the elementary symmetric polynomials in the roots), how can one recover the roots?This leads to studying solutions of polynomials using the permutation group of the roots, originally in the form of Lagrange resolvents, later developed in Galois theory.
Consider a monic polynomial in t of degree n
| n+a | |
| P=t | |
| n-1 |
tn-1
| 2+a | |
| + … +a | |
| 1t+a |
0
with coefficients ai in some field K. There exist n roots x1,...,xn of P in some possibly larger field (for instance if K is the field of real numbers, the roots will exist in the field of complex numbers); some of the roots might be equal, but the fact that one has all roots is expressed by the relation
P=
| n+a | |
| t | |
| n-1 |
tn-1
| 2+a | |
| + … +a | |
| 1t+a |
0=(t-x1)(t-x2) … (t-xn).
By comparing coefficients one finds that
\begin{align} an-1&=-x1-x2- … -xn\\ an-2&=x1x2+x1x3+ … +x2x3+ … +xn-1xn=style\sum1\leqxixj\\ &{}
| n-1 | |
| \vdots\\ a | |
| 1&=(-1) |
(x2x3 … xn+x1x3x4 … xn+ … +x1x2 … xn-2xn+x1x2 … xn-1) =style(-1)n-1
| n\prod | |
| \sum | |
| j ≠ i |
xj\\ a
| nx | |
| 1x |
2 … xn. \end{align}
These are in fact just instances of Vieta's formulas. They show that all coefficients of the polynomial are given in terms of the roots by a symmetric polynomial expression: although for a given polynomial P there may be qualitative differences between the roots (like lying in the base field K or not, being simple or multiple roots), none of this affects the way the roots occur in these expressions.
Now one may change the point of view, by taking the roots rather than the coefficients as basic parameters for describing P, and considering them as indeterminates rather than as constants in an appropriate field; the coefficients ai then become just the particular symmetric polynomials given by the above equations. Those polynomials, without the sign
(-1)n-i
There are a few types of symmetric polynomials in the variables X1, X2, ..., Xn that are fundamental.
See main article: Elementary symmetric polynomial. For each nonnegative integer k, the elementary symmetric polynomial ek(X1, ..., Xn) is the sum of all distinct products of k distinct variables. (Some authors denote it by σk instead.) For k = 0 there is only the empty product so e0(X1, ..., Xn) = 1, while for k > n, no products at all can be formed, so ek(X1, X2, ..., Xn) = 0 in these cases. The remaining n elementary symmetric polynomials are building blocks for all symmetric polynomials in these variables: as mentioned above, any symmetric polynomial in the variables considered can be obtained from these elementary symmetric polynomials using multiplications and additions only. In fact one has the following more detailed facts:
For example, for n = 2, the relevant elementary symmetric polynomials are e1(X1, X2) = X1 + X2, and e2(X1, X2) = X1X2. The first polynomial in the list of examples above can then be written as
| 3-7=e | |
| X | |
| 1(X |
1,X
| 3-3e | |
| 2(X |
1,X2)e1(X1,X2)-7
Powers and products of elementary symmetric polynomials work out to rather complicated expressions. If one seeks basic additive building blocks for symmetric polynomials, a more natural choice is to take those symmetric polynomials that contain only one type of monomial, with only those copies required to obtain symmetry. Any monomial in X1, ..., Xn can be written as X1α1...Xnαn where the exponents αi are natural numbers (possibly zero); writing α = (α1,...,αn) this can be abbreviated to X α. The monomial symmetric polynomial mα(X1, ..., Xn) is defined as the sum of all monomials xβ where β ranges over all distinct permutations of (α1,...,αn). For instance one has
m(3,1,1)(X1,X2,X3)=X
| 3X | |
| 2X |
3+X1X
| 3X | |
| 3+X |
1X2X
| 3 | |
| 3 |
m(3,2,1)(X1,X2,X3)=X
| 2X | |
| 3+X |
| 3X | |
| 2X |
| 3X | |
| 3+X |
| 2X | |
| 2X |
| 3+X | |
| 1X |
| 2+X | |
| 1X |
| 3. | |
| 3 |
The elementary symmetric polynomials are particular cases of monomial symmetric polynomials: for 0 ≤ k ≤ n one has
ek(X1,\ldots,Xn)=m\alpha(X1,\ldots,Xn)
See main article: Power sum symmetric polynomial. For each integer k ≥ 1, the monomial symmetric polynomial m(k,0,...,0)(X1, ..., Xn) is of special interest. It is the power sum symmetric polynomial, defined as
pk(X1,\ldots,Xn)=
| k | |
| X | |
| 1 |
+
| k | |
| X | |
| 2 |
+ … +
| k | |
| X | |
| n |
.
Any symmetric polynomial in X1, ..., Xn can be expressed as a polynomial expression with rational coefficients in the power sum symmetric polynomials p1(X1, ..., Xn), ..., pn(X1, ..., Xn).In particular, the remaining power sum polynomials pk(X1, ..., Xn) for k > n can be so expressed in the first n power sum polynomials; for example
p3(X1,X
|
1,X2)p1(X1,X
|
1,X
| 3. | |
| 2) |
In contrast to the situation for the elementary and complete homogeneous polynomials, a symmetric polynomial in n variables with integral coefficients need not be a polynomial function with integral coefficients of the power sum symmetric polynomials.For an example, for n = 2, the symmetric polynomial
m(2,1)(X1,X2)=
| 2 | |
| X | |
| 1 |
X2+X1
| 2 | |
| X | |
| 2 |
m(2,1)(X1,X2)=
| ||||
| 1,X |
| ||||
| 1,X |
2)p1(X1,X2).
\begin{align}m(2,1)(X1,X2,X3)&=
| 2 | |
| X | |
| 1 |
X2+X1
| 2 | |
| X | |
| 2 |
+
| 2 | |
| X | |
| 1 |
X3+X1
| 2 | |
| X | |
| 3 |
+
| 2 | |
| X | |
| 2 |
X3+X2
| 2\\ | |
| X | |
| 3 |
&=p1(X1,X2,X3)p2(X1,X2,X3)-p3(X1,X2,X3). \end{align}
See main article: Complete homogeneous symmetric polynomial. For each nonnegative integer k, the complete homogeneous symmetric polynomial hk(X1, ..., Xn) is the sum of all distinct monomials of degree k in the variables X1, ..., Xn. For instance
h3(X1,X2,X3)=
| 2X | |
| X | |
| 2+X |
| 2X | |
| 3+X |
1X
| 2+X | |
| 1X |
2X3+X1X
| 2X | |
| 3+X |
2X
| 3. | |
| 3 |
\begin{align} h3(X1,X2,X3)&=m(3)(X1,X2,X3)+m(2,1)(X1,X2,X3)+m(1,1,1)(X1,X2,X3)\\
| 2X | |
| &=(X | |
| 2+X |
| 2X | |
| 3+X |
1X
| 2+X | |
| 1X |
| 2X | |
| 3+X |
2X
| 2)+(X | |
| 1X |
2X3).\\ \end{align}
All symmetric polynomials in these variables can be built up from complete homogeneous ones: any symmetric polynomial in X1, ..., Xn can be obtained from the complete homogeneous symmetric polynomials h1(X1, ..., Xn), ..., hn(X1, ..., Xn) via multiplications and additions. More precisely:
Any symmetric polynomial P in X1, ..., Xn can be written as a polynomial expression in the polynomials hk(X1, ..., Xn) with 1 ≤ k ≤ n.
If P has integral coefficients, then the polynomial expression also has integral coefficients.For example, for n = 2, the relevant complete homogeneous symmetric polynomials are and . The first polynomial in the list of examples above can then be written as
| 3+ | |
| X | |
| 1 |
| 3-7 | |
| X | |
| 2 |
=-2h1(X1,X
| 3+3h | |
| 1(X |
1,X2)h2(X1,X2)-7.
An important aspect of complete homogeneous symmetric polynomials is their relation to elementary symmetric polynomials, which can be expressed as the identities
| k(-1) | |
| \sum | |
| i=0 |
iei(X1,\ldots,Xn)hk-i(X1,\ldots,Xn)=0
See main article: Schur polynomial. Another class of symmetric polynomials is that of the Schur polynomials, which are of fundamental importance in the applications of symmetric polynomials to representation theory. They are however not as easy to describe as the other kinds of special symmetric polynomials; see the main article for details.
Symmetric polynomials are important to linear algebra, representation theory, and Galois theory. They are also important in combinatorics, where they are mostly studied through the ring of symmetric functions, which avoids having to carry around a fixed number of variables all the time.
See main article: Alternating polynomials.
Analogous to symmetric polynomials are alternating polynomials: polynomials that, rather than being invariant under permutation of the entries, change according to the sign of the permutation.
These are all products of the Vandermonde polynomial and a symmetric polynomial, and form a quadratic extension of the ring of symmetric polynomials: the Vandermonde polynomial is a square root of the discriminant.