Open Journal of Mathematical Sciences
ISSN: 2523-0212 (Online) 2616-4906 (Print)
DOI: 10.30538/oms2020.0096
Characterization of a vector measure: application in the \(GL(2;\mathbb{R})\) group
Abalo Douhadji\(^1\), Yaovi Awussi
Department of Mathematics, University of Lomé, PObox 1515, Lomé, Togo.; (A.D)
Department of Mathematics, Mathematics and Applications Laboratory, University of Lomé, PObox 1515, Lomé, Togo.; (Y.A)
\(^{1}\)Corresponding Author: douhadjiabalo@gmail.com
Abstract
Keywords:
1. Introduction
In 1989, Assiamoua [1] worked on the properties of vector measure, introduced by Diestel in [2]. In 2013, Awussi [3] proved that any bounded vector measure is absolutely continue with respect to Haar measure. In 2013, Mensah [4] worked on Fourier-Stieljes transform of vector measures on compact groups. In this paper, we treat with a special case by giving a form to a bounded vector measure on \(G=GL(2;\mathbb{R})\). We consider a vector measure which is absolutely continue with respect to Haar measure and then give the integral form [5] to this vector measure. The first essential part of our work is to establish the form of Haar measure on \(G=GL(2;\mathbb{R})\). We prove that \begin{equation*} \mu(f)=\int_{\mathbb{R}^{4}}\dfrac{f(x_{11}; x_{12};x_{21}; x_{22})}{(x_{11} x_{22}-x_{12} x_{21})^{2}}dx_{11}dx_{12}dx_{21}dx_{22}; \end{equation*} \(\forall\, f\in K(G;E)\) and \(x=\left( \begin{array}{cc} x_{11} & x_{12} \\ x_{21} & x_{22} \end{array}\right)\in GL(2;\mathbb{R})\); is a Haar measure on \( G=GL(2;\mathbb{R})\). Once this demonstration achieved we go straight to generalize the form of a vector measure on \( K(GL(2;\mathbb{R});\mathbb{R}^{4})\). This paper is organized as follows: in Section 2, we give some definitions related to vector measure and matrices and prove the fundamental theorem which will help us in proving our main result and in Section 3, we present our main result.Preliminaries
In this section, we give basic definitions and concepts concerning with vector measure and Lie groups.Definition 1.[2] Let \(G\) be a locally compact group and \(K(G;E)\) be the space of \(E\) valued functions with compact support on \(G.\) A vector measure on \(G\) with respect to Banach spaces \(E\) and \(F\) is a linear map: \begin{eqnarray*} m:& K(G;E)&\to F \\ &f& \mapsto m(f) \end{eqnarray*} such as \(\forall\,\, K \) compact in \(G\) \(\exists \,\,a_{K} > 0, \| m(f) \|_{F} \leq a_{K}\|f \|_{\infty}.\) Where \(\| . \|_{F}\) is the norm on Banach spaces \(F\) and \(\|f \|_{\infty}= sup \{ \|f(t)\|_{E}, t \in G \}\) is the norm on \(K(G;E).\)
The value \( m(f)\) of \(m\) in \(f \in K(G;E)\) is called integral of \(f\) with respect to \(m\) and can be written as [5, 6]: \begin{equation*} \int_{G} f(t)dm(t)= m(f). \end{equation*} We consider \(GL(2;\mathbb{R})\) is the set of matrices of order two with real coefficients whose determinant is not equal to zero, i.e., $$GL(2;\mathbb{R})=\left\lbrace g = \left( \begin{array}{cc} g_{11} & g_{12} \\ g_{21} & g_{22} \end{array}\right); g_{ij}\in \mathbb{R};1\leqslant i,j\leqslant 2 | detg \neq 0 \right\rbrace. $$ \(G= GL(2;\mathbb{R})\) is a Lie group. Also \(G\) is a manifold such that, at any point \(g\in G\), there exists an open \(V_{g}\) of \(G\), an open \(U_{g}\) of \(\mathbb{R}^{4}\) and \(\varphi_{g}\) a diffeomorphism of \(V_{g}\) in \(U_{g}\). So each \(x=\left( \begin{array}{cc} x_{11} & x_{12} \\ x_{21} & x_{22} \end{array}\right)\in GL(2;\mathbb{R})\) is assimilated to \((x_{11}; x_{12};x_{21}; x_{22})\) of \(\mathbb{R}^{4}.\) In order to prove our main result, first we prove following fundamental theorem which allow us to get our final result. The following theorem gives us Haar's measure on \(GL(2;\mathbb{R}).\)Theorem 1. Let \(K(G;E)\) be the space of \(E\) valued functions with compact support on \(G\), where \(G= GL(2;\mathbb{R})\) and \( E=\mathbb{R}^{4}\). Then \( \mu:K(G;E)\to \mathbb{R}^{+}\) defined as
Proof. If \(\mu\) is a Haar measure on \(G= GL(2;\mathbb{R})\) then \(d\mu(x)=\dfrac{1}{(detx)^{2}}dx, \quad \forall\,\, x \in G \). As \begin{equation*} d\mu(x)=\dfrac{1}{(x_{11} x_{22}-x_{12} x_{21})^{2}}dx_{11}dx_{12}dx_{21}dx_{22}. \end{equation*} Since \(\mu(f)=\int_{G}f(x)d\mu(x),\,\forall\, f\in K(G;E)\), we get:
Theorem 2. Let \(m\) be a bounded vector measure on compact Lie group \(G\) and \(E\) and \(F\) two Banach spaces. If \(m\) is a continuous alternating linear form in \(L^{p}(G;E)\) then \(m\) is absolutely continuous.
The following theorems are important, because once we establish the form of the Haar measure on \(G \), it will be easy to establish a vector measure on \(K(G;E).\)Theorem 3. [3] Let \(G\) be a compact group, \(m\) be a bounded vector measure on \(G\) and \(p\) and \(q\) are two conjugates numbers with \( p\geq 1 \). Then the following two assertions are equivalent:
- \( \forall \, h \in L^{p}(G;E),m\ast h \in C(G;E), \)
- \( \exists \, f \in L^{q}(G;E)\; such \; as \quad m = f\mu. \)
Theorem 4.[3] Let \(\mu \) be a Haar measure on compact Lie group \(G\), \(p \in [1,\infty[\) and \(q\) conjugate of \(p\). If \(\phi\) is a linear continuous form on \(L^{p}(G;E)\) then there exists a map \(f \in L^{q}(G,E)\) such as for any \(g \in L^{p}\), we have \(\phi(g)=\int_{G} gfd\mu. \)
We use the duality theorem for \(p= 1 \) and \( q=\infty.\)3. Main result
In this section, we give our main result.Theorem 5. Let \(K(G;E)\) be the space of \(E\) valued functions with compact support on \(G\), where \(G= GL(2;\mathbb{R})\) and \( E=\mathbb{R}^{4}\). If \(m\) is a vector measure on \(K(G;E)\), then
Proof. Since \(m\) being a vector measure on \(K(GL(2;\mathbb{R});\mathbb{R}^{4})\), so \(m\) is continuous, alternating and bounded linear form. Using Theorem 2, we get \(m \ll \mu\). The Theorems 3 and 4 allow us to write \(dm=gd\mu;\quad g\in L^{\infty}(GL(2;\mathbb{R}))\), which implies \begin{eqnarray*} dm(x)&=& \dfrac{g(x)}{(detx)^{2}}dx; \\ m(f)&=& \int_{G}\dfrac{g(x)f(x)}{(detx)^{2}}dx \quad f\in K(GL(2;\mathbb{R});\mathbb{R}^{4}) \\ &=& \int_{\mathbb{R}^{4}}\dfrac{g(x_{11}; x_{12};x_{21}; x_{22})f(x_{11}; x_{12};x_{21}; x_{22})}{(x_{11} x_{22}-x_{12} x_{21})^{2}}dx_{11}dx_{12}dx_{21}dx_{22}. \end{eqnarray*}
Acknowledgments
The authors would like to express their thanks to the referees for their useful remarks and encouragements.Author contributions
All authors contributed equally to the writing of this paper. All authors read and approved the final manuscript.Conflict of interests
The authors declare no conflict of interest.References
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