Talk:PlanetPhysics/Groupoid Representations Induced by Measure

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%%% Primary Title: groupoid representations induced by measure
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\begin{document}

 \begin{definition}
A \emph{groupoid representation induced by measure} can be defined as measure induced \htmladdnormallink{operators}{http://planetphysics.us/encyclopedia/QuantumOperatorAlgebra4.html} or as operators induced by a measure preserving map in the context of \htmladdnormallink{Haar systems}{http://planetphysics.us/encyclopedia/QuantumOperatorAlgebra5.html} with measure associated with \htmladdnormallink{locally compact groupoids}{http://planetphysics.us/encyclopedia/LocallyCompactGroupoid.html}, $\mathbf{G_{lc}}$. Thus, let us consider a locally compact groupoid
$\mathbf{G_{lc}}$ endowed with an associated Haar system
$\nu = \left\{\nu^u, u \in U_{\mathbf{G_{lc}}} \right\}$, and $\mu$
a quasi-invariant measure on $U_{\mathbf{G_{lc}}}$.
Moreover, let $(X_1, \mathfrak{B}_1, \mu_1)$ and $(X_2, \mathfrak{B}_2, \mu_2)$ be \htmladdnormallink{measure spaces}{http://planetphysics.us/encyclopedia/LebesgueMeasure.html} and denote by $L^0(X_1)$ and $L^0(X_2)$ the corresponding spaces of \htmladdnormallink{measurable functions}{http://planetphysics.us/encyclopedia/LebesgueMeasure.html} (with values in $\mathbb{C}$). Let us also recall that with a measure-preserving transformation $T: X_1 \longrightarrow X_2$ one can define an \emph{operator induced by a measure preserving map}, $U_T:L^0(X_2) \longrightarrow L^0(X_1)$ as follows.

\begin{displaymath}
(U_T f)(x):=f(Tx)\,, \qquad\qquad f \in L^0(X_2),\; x \in X_1
\end{displaymath}

Next, let us define $\nu = \int \nu^u d\mu (u)$ and also define $\nu^{-1}$ as the mapping
$x \mapsto x^{-1}$. With $f \in C_c(\mathbf{G_{lc}})$, one can now define the
\emph{measure induced \htmladdnormallink{operator}{http://planetphysics.us/encyclopedia/QuantumSpinNetworkFunctor2.html}} $\textbf{Ind}\mu (f) $ as an operator being defined on $L^2(\nu^{-1})$
by the \htmladdnormallink{formula}{http://planetphysics.us/encyclopedia/Formula.html}:
$$\textbf{Ind}\mu (f)\xi(x)= \int f(y) \xi(y^{-1}x)d\nu^{r(x)}(y) = f * \xi(x) $$
\end{definition}

\textbf{Remark:}

One can readily verify that :

$$\left\| \textbf{Ind}\mu(f) \right\| \leq \left\| f \right\|_1 $$,

and also that $\textbf{Ind}\mu$ is a proper \htmladdnormallink{representation}{http://planetphysics.us/encyclopedia/CategoricalGroupRepresentation.html} of $C_c(\mathbf{G_{lc}})$, in the sense that the latter is usually defined for \htmladdnormallink{groupoids}{http://planetphysics.us/encyclopedia/QuantumOperatorAlgebra5.html}.

\end{document}
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