Revision as of 00:41, 22 April 2025 by Bot (Created page with "<div class="d-none"><math> \newcommand{\mathds}{\mathbb}</math></div> {{Alert-warning|This article was automatically generated from a tex file and may contain conversion errors. If permitted, you may login and edit this article to improve the conversion. }}Given <math>X\subset S^{N-1}_{\mathbb C,+}</math> and <math>K\in\mathbb N</math> as above, consider the submanifold <math>X^{(K)}\subset X</math> obtained by factorizing the universal <math>K\times K</math> model: <...")
BBot
Apr 22'25
Exercise
[math]
\newcommand{\mathds}{\mathbb}[/math]
This article was automatically generated from a tex file and may contain conversion errors. If permitted, you may login and edit this article to improve the conversion.
Given [math]X\subset S^{N-1}_{\mathbb C,+}[/math] and [math]K\in\mathbb N[/math] as above, consider the submanifold [math]X^{(K)}\subset X[/math] obtained by factorizing the universal [math]K\times K[/math] model:
[[math]]
\pi_K:C(X)\to C(X^{(K)})\subset M_K(C(T_K))
[[/math]]
Prove that at [math]K=1[/math] we obtain in this way the classical version of [math]X[/math],
[[math]]
X^{(1)}=X_{class}
[[/math]]
and that at [math]K\geq2[/math], assuming that [math]X[/math] is a compact quantum group, [math]X=G\subset U_n^+[/math] with [math]N=n^2[/math], the space [math]X^{(K)}[/math] is not necessarily a compact quantum group.