Weingarten function

In mathematics, Weingarten functions are rational functions indexed by partitions of integers that can be used to calculate integrals of products of matrix coefficients over classical groups. They were first studied by Template:Harvtxt who found their asymptotic behavior, and named by Template:Harvtxt, who evaluated them explicitly for the unitary group.

Weingarten functions are used for evaluating integrals over the unitary group U_d of products of matrix coefficients of the form

${\displaystyle \underset{U_d}{\int }{U}_{i_1{j}_1}\cdots U_{i_q{j}_q}{U}_{i_1^{\prime }{j}_1^{\prime }}^{*}\cdots U_{i_q^{\prime }{j}_q^{\prime }}^{*}dU,}$

where ${\displaystyle *}$ denotes complex conjugation. Note that ${\displaystyle U_{ji}^{*}=(U^{†}{)}_{ij}}$ where ${\displaystyle U^{†}}$ is the conjugate transpose of ${\displaystyle U}$, so one can interpret the above expression as being for the ${\displaystyle i_1{j}_1\dots i_q{j}_{q}j{\text{'}}_{1}i{\text{'}}_1\dots j{\text{'}}_{q}i{\text{'}}_q}$ matrix element of ${\displaystyle U\otimes \cdots \otimes U\otimes U^{†}\otimes \cdots \otimes U^{†}}$.

This integral is equal to

${\displaystyle \sum _{\sigma ,\tau \in S_q}{\delta }_{i_1{i}_{\sigma (1)}^{\prime }}\cdots {\delta }_{i_q{i}_{\sigma (q)}^{\prime }}{\delta }_{j_1{j}_{\tau (1)}^{\prime }}\cdots {\delta }_{j_q{j}_{\tau (q)}^{\prime }}Wg(\sigma {\tau }^{-1},d)}$

where Wg is the Weingarten function, given by

${\displaystyle Wg(\sigma ,d)=\frac{1}{q{!}^2}\sum _{\lambda }\frac{{\chi }^{\lambda }(1{)}^2{\chi }^{\lambda }(\sigma )}{s_{\lambda ,d}(1)}}$

where the sum is over all partitions λ of q Template:Harv. Here χ^λ is the character of S_q corresponding to the partition λ and s is the Schur polynomial of λ, so that s_λd(1) is the dimension of the representation of U_d corresponding to λ.

The Weingarten functions are rational functions in d. They can have poles for small values of d, which cancel out in the formula above. There is an alternative inequivalent definition of Weingarten functions, where one only sums over partitions with at most d parts. This is no longer a rational function of d, but is finite for all positive integers d. The two sorts of Weingarten functions coincide for d larger than q, and either can be used in the formula for the integral.

The first few Weingarten functions Wg(σ, d) are

${\displaystyle {\displaystyle Wg(,d)=1}}$ (The trivial case where q = 0)

${\displaystyle {\displaystyle Wg(1,d)=\frac{1}{d}}}$

${\displaystyle {\displaystyle Wg(2,d)=\frac{-1}{d(d^2-1)}}}$

${\displaystyle {\displaystyle Wg(1^2,d)=\frac{1}{d^2-1}}}$

${\displaystyle {\displaystyle Wg(3,d)=\frac{2}{d(d^2-1)(d^2-4)}}}$

${\displaystyle {\displaystyle Wg(21,d)=\frac{-1}{(d^2-1)(d^2-4)}}}$

${\displaystyle {\displaystyle Wg(1^3,d)=\frac{d^2-2}{d(d^2-1)(d^2-4)}}}$

${\displaystyle {\displaystyle Wg(4,d)=\frac{-5}{d(d^2-1)(d^2-4)(d^2-9)}}}$

${\displaystyle {\displaystyle Wg(31,d)=\frac{2d^2-3}{d^2(d^2-1)(d^2-4)(d^2-9)}}}$

${\displaystyle {\displaystyle Wg(2^2,d)=\frac{d^2+6}{d^2(d^2-1)(d^2-4)(d^2-9)}}}$

${\displaystyle {\displaystyle Wg(21^2,d)=\frac{-1}{d(d^2-1)(d^2-9)}}}$

${\displaystyle {\displaystyle Wg(1^4,d)=\frac{d^4-8d^2+6}{d^2(d^2-1)(d^2-4)(d^2-9)}}}$

where permutations σ are denoted by their cycle shapes.

There exist computer algebra programs to produce these expressions.^[1][2]

The explicit expressions for the integrals of first- and second-degree polynomials, obtained via the formula above, are:$${\displaystyle \underset{U_d}{\int }dU{U}_{ij}{\overline{U}}_{k\ell }={\delta }_{ik}{\delta }_{j\ell }\mathrm{Wg}(1,d)=\frac{{\delta }_{ik}{\delta }_{j\ell }}{d}.}$$$${\displaystyle \underset{U_d}{\int }dU{U}_{ij}{U}_{k\ell }{\overline{U}}_{mn}{\overline{U}}_{pq}=({\delta }_{im}{\delta }_{jn}{\delta }_{kp}{\delta }_{\ell q}+{\delta }_{ip}{\delta }_{jq}{\delta }_{km}{\delta }_{\ell n})\mathrm{Wg}(1^2,d)+({\delta }_{im}{\delta }_{jq}{\delta }_{kp}{\delta }_{\ell n}+{\delta }_{ip}{\delta }_{jn}{\delta }_{km}{\delta }_{\ell q})\mathrm{Wg}(2,d).}$$

For large d, the Weingarten function Wg has the asymptotic behavior

${\displaystyle Wg(\sigma ,d)=d^{-n-|\sigma |}\prod _i(-1{)}^{|C_i|-1}{c}_{|C_i|-1}+O(d^{-n-|\sigma |-2})}$

where the permutation σ is a product of cycles of lengths C_i, and c_n = (2n)!/n!(n + 1)! is a Catalan number, and |σ| is the smallest number of transpositions that σ is a product of. There exists a diagrammatic method^[3] to systematically calculate the integrals over the unitary group as a power series in 1/d.

For orthogonal and symplectic groups the Weingarten functions were evaluated by Template:Harvtxt. Their theory is similar to the case of the unitary group. They are parameterized by partitions such that all parts have even size.

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