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--- bistochastic_group [2020/02/12 09:15]
amang [Definition]
+++ bistochastic_group [2021/11/23 11:56] (current)
@@ Line 1: / Line 1: @@
 ====== Bistochastic group ======
-A **bistochastic group** is any member of a sequence $(B_N)_{N\in \N}$ of [[classical matrix groups]].
+A **bistochastic group** is any member of a sequence $(B_N)_{N\in \N}$ of [[classical orthogonal matrix groups]].
 ===== Definition =====
@@ Line 10: / Line 10: @@
   * **bistochastic** or **doubly stochastic** if $u$ is both right and left stochastic.
-For every $N\in \N$ the **bistochastic group** for dimension $N$ is the subgroup of the [[wp>general linear group]] $\mathrm{GL}(N,\C)$ given by all bistochastic orthogonal $N\times N$-matrices, i.e., the set
+For every $N\in \N$ the **bistochastic group** for dimension $N$ is the subgroup of the [[wp>general linear group]] $\mathrm{GL}(N,\C)$ given by all bistochastic [[orthogonal group|orthogonal]] $N\times N$-matrices, i.e., the set
-$$B_N\colon\hspace{-0.6em}=\{ u\in \C^{N\times N}\,\vert\, u=\overline{u},\, uu^t=u^tu=I, \, {\textstyle\sum_{\ell=1}^N} u_{i,\ell}={\textstyle\sum_{k=1}^N} u_{k,j}=1\},$$
+$$B_N\colon\hspace{-0.6em}=\{ u\in \C^{N\times N}\,\vert\, u=\overline{u},\, uu^t=u^tu=I, \, \forall_{i,j=1}^N: {\textstyle\sum_{\ell=1}^N} u_{i,\ell}={\textstyle\sum_{k=1}^N} u_{k,j}=1\},$$
-where, if $u=(u_{i,j})_{i,j=1}^N$, then $\overline u=(u^\ast_{i,j})_{i,j=1}^N$ is the complex conjugate of $u$ and $u^t=(u_{j,i})_{i,j=1}^N$ the transpose and where $I_N$ is the identity $N\!\times \!N$-matrix.
+where, if $u=(u_{i,j})_{i,j=1}^N$, then $\overline u=(\overline{u}_{i,j})_{i,j=1}^N$ is the complex conjugate of $u$ and $u^t=(u_{j,i})_{i,j=1}^N$ the transpose and where $I_N$ is the identity $N\!\times \!N$-matrix.
 Note that the elements of $B_N$ are __not__ required to have non-negative entries. Stochastic matrices with non-negative entries are known as **probability matrices**, **transition matrices**, **substitution matrices** or **Markov matrices**. The set of such $N\times N$-matrices forms a compact Hausdorff semigroup with respect to the topology inherited from $\C^{N\times N}$ -- but not a group. In fact, a bistochastic matrix with non-negative entries has a bistochastic inverse with non-negative entries if and only if it is a permutation matrix [(:ref:MonPle73)].
+===== Basic properties =====
+The bistochastic groups $(B_N)_{N\in \N}$ are an [[easy_quantum_group|easy]] family of compact matrix quantum groups, i.e., the intertwiner spaces of their corepresentation categories are induced by a [[category of partitions]]. More precisely, it is the [[category of all partitions with small blocks]] that induces the corepresentation categories of $(B_N)_{N\in \N}$. Its canonical generating set of partitions is $\{\crosspart,\singleton\}$.
+===== Representation theory =====
+===== Cohomology =====
+===== Related quantum groups =====
 ===== References =====

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