Muirhead's inequality

In mathematics, Muirhead's inequality, named after Robert Franklin Muirhead, also known as the "bunching" method, generalizes the inequality of arithmetic and geometric means.

For any real vector

${\displaystyle a=(a_1,\dots ,a_n)}$

define the "a-mean" [a] of positive real numbers x₁, ..., x_n by

${\displaystyle [a]=\frac{1}{n!}\sum _{\sigma }{x}_{{\sigma }_1}^{a_1}\cdots x_{{\sigma }_n}^{a_n},}$

where the sum extends over all permutations σ of { 1, ..., n }.

When the elements of a are nonnegative integers, the a-mean can be equivalently defined via the monomial symmetric polynomial ${\displaystyle m_a(x_1,\dots ,x_n)}$ as

${\displaystyle [a]=\frac{k_1!\cdots k_l!}{n!}{m}_a(x_1,\dots ,x_n),}$

where ℓ is the number of distinct elements in a, and k₁, ..., k_ℓ are their multiplicities.

Notice that the a-mean as defined above only has the usual properties of a mean (e.g., if the mean of equal numbers is equal to them) if ${\displaystyle a_1+\cdots +a_n=1}$. In the general case, one can consider instead ${\displaystyle [a{]}^{1/(a_1+\cdots +a_n)}}$, which is called a Muirhead mean.^[1]

Examples

• For a = (1, 0, ..., 0), the a-mean is just the ordinary arithmetic mean of x₁, ..., x_n.
• For a = (1/n, ..., 1/n), the a-mean is the geometric mean of x₁, ..., x_n.
• For a = (x, 1 − x), the a-mean is the Heinz mean.
• The Muirhead mean for a = (−1, 0, ..., 0) is the harmonic mean.

Main page: Doubly stochastic matrix

An n × n matrix P is doubly stochastic precisely if both P and its transpose P^T are stochastic matrices. A stochastic matrix is a square matrix of nonnegative real entries in which the sum of the entries in each column is 1. Thus, a doubly stochastic matrix is a square matrix of nonnegative real entries in which the sum of the entries in each row and the sum of the entries in each column is 1.

Muirhead's inequality states that [a] ≤ [b] for all x such that x_i > 0 for every i ∈ { 1, ..., n } if and only if there is some doubly stochastic matrix P for which a = Pb.

Furthermore, in that case we have [a] = [b] if and only if a = b or all x_i are equal.

The latter condition can be expressed in several equivalent ways; one of them is given below.

The proof makes use of the fact that every doubly stochastic matrix is a weighted average of permutation matrices (Birkhoff-von Neumann theorem).

Because of the symmetry of the sum, no generality is lost by sorting the exponents into decreasing order:

${\displaystyle a_1\ge a_2\ge \cdots \ge a_n}$

${\displaystyle b_1\ge b_2\ge \cdots \ge b_n.}$

Then the existence of a doubly stochastic matrix P such that a = Pb is equivalent to the following system of inequalities:

${\displaystyle \begin{array}{rl}{a}_1& \le b_1\\ a_1+a_2& \le b_1+b_2\\ a_1+a_2+a_3& \le b_1+b_2+b_3\\ & ⋮\\ a_1+\cdots +a_{n-1}& \le b_1+\cdots +b_{n-1}\\ a_1+\cdots +a_n& =b_1+\cdots +b_n.\end{array}}$

(The last one is an equality; the others are weak inequalities.)

The sequence ${\displaystyle b_1,\dots ,b_n}$ is said to majorize the sequence ${\displaystyle a_1,\dots ,a_n}$.

It is convenient to use a special notation for the sums. A success in reducing an inequality in this form means that the only condition for testing it is to verify whether one exponent sequence (${\displaystyle {\alpha }_1,\dots ,{\alpha }_n}$) majorizes the other one.

${\displaystyle \sum _{\text{sym}}{x}_1^{{\alpha }_1}\cdots x_n^{{\alpha }_n}}$

This notation requires developing every permutation, developing an expression made of n! monomials, for instance:

${\displaystyle \begin{array}{rl}\sum _{\text{sym}}{x}^3{y}^2{z}^0& =x^3{y}^2{z}^0+x^3{z}^2{y}^0+y^3{x}^2{z}^0+y^3{z}^2{x}^0+z^3{x}^2{y}^0+z^3{y}^2{x}^0\\ & =x^3{y}^2+x^3{z}^2+y^3{x}^2+y^3{z}^2+z^3{x}^2+z^3{y}^2\end{array}}$

Main page: Inequality of arithmetic and geometric means

Let

${\displaystyle a_G=(\frac{1}{n},\dots ,\frac{1}{n})}$

and

${\displaystyle a_A=(1,0,0,\dots ,0).}$

We have

${\displaystyle \begin{array}{rl}{a}_{A1}=1& >a_{G1}=\frac{1}{n},\\ a_{A1}+a_{A2}=1& >a_{G1}+a_{G2}=\frac{2}{n},\\ & ⋮\\ a_{A1}+\cdots +a_{An}& =a_{G1}+\cdots +a_{Gn}=1.\end{array}}$

Then

[a_A] ≥ [a_G],

which is

${\displaystyle \frac{1}{n!}(x_1^1\cdot x_2^0\cdots x_n^0+\cdots +x_1^0\cdots x_n^1)(n-1)!\ge \frac{1}{n!}(x_1\cdot \cdots \cdot x_n{)}^{1/n}n!}$

yielding the inequality.

We seek to prove that x² + y² ≥ 2xy by using bunching (Muirhead's inequality). We transform it in the symmetric-sum notation:

${\displaystyle \sum _{\mathrm{s}\mathrm{y}\mathrm{m}}{x}^2{y}^0\ge \sum _{\mathrm{s}\mathrm{y}\mathrm{m}}{x}^1{y}^1.}$

The sequence (2, 0) majorizes the sequence (1, 1), thus the inequality holds by bunching.

Similarly, we can prove the inequality

${\displaystyle x^3+y^3+z^3\ge 3xyz}$

by writing it using the symmetric-sum notation as

${\displaystyle \sum _{\mathrm{s}\mathrm{y}\mathrm{m}}{x}^3{y}^0{z}^0\ge \sum _{\mathrm{s}\mathrm{y}\mathrm{m}}{x}^1{y}^1{z}^1,}$

which is the same as

${\displaystyle 2x^3+2y^3+2z^3\ge 6xyz.}$

Since the sequence (3, 0, 0) majorizes the sequence (1, 1, 1), the inequality holds by bunching.

• Inequality of arithmetic and geometric means
• Doubly stochastic matrix
• Monomial symmetric polynomial

• Combinatorial Theory by John N. Guidi, based on lectures given by Gian-Carlo Rota in 1998, MIT Copy Technology Center, 2002.
• Kiran Kedlaya, A < B (A less than B), a guide to solving inequalities
• Muirhead's theorem at PlanetMath.org.
• Hardy, G.H.; Littlewood, J.E.; Pólya, G. (1952), Inequalities, Cambridge Mathematical Library (2. ed.), Cambridge: Cambridge University Press, ISBN 0-521-05206-8, MR0046395, Zbl 0047.05302, Section 2.18, Theorem 45.

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