Tensors,matchings and codes

We exploit the structure of the critical orbital sets of symmetry classes of tensors associated to sign uniform partitions and we establish new connections between symmetry classes of tensors, matchings on bipartite graphs and coding theory. In particular, we prove that the orthogonal dimension of the critical orbital sets associated to single hook partitions $\lambda =(w\text{,}{1}^{n-w})$ equals the value of the coding theoretic function $A(n\text{,}4\text{,}w)$. When $w=2$ we reobtain this number as the independence number of the Dynkin diagram $A_{n-1}$.     

A satellite of the grand Furuta inequality and its application

The grand Furuta inequality has the following satellite (SGF;$t\in [0\text{,}1]$), given as a mean theoretic expression:$A?B>0\text{,}t\in [0\text{,}1]?A^{-r+t}{\#}_{\frac{1-t+r}{(p-t)s+r}}(A^t{?}_s{B}^p)?B\text{for}r?t\text{;}p\text{,}s?1\text{,}$where ${\#}_{\alpha }$ is the $\alpha$-geometric mean and ${?}_s$ ($s?[0\text{,}1]$) is a formal extension of ${\#}_{\alpha }$. It is shown that (SGF; $t\in [0\text{,}1]$) has the Löwner–Heinz property, i.e. (SGF; $t=1$) implies (SGF;t) for every $t\in [0\text{,}1]$. Furthermore, we show that a recent further extension of (GFI) by Furuta himself has also the Löwner–Heinz property.     

The existence of solutions for boundary value problem of fractional hybrid differential equations

In this paper, we study the existence of solutions for the boundary value problem of fractional hybrid differential equations$D_{0^{+}}^{\alpha }\left[\frac{x(t)}{f(t\text{,}x(t))}\right]+g(t\text{,}x(t))=0\text{,}0<t<1\text{,}$$x(0)=x(1)=0\text{,}$where $1<\alpha ?2$ is a real number, $D_{0^{+}}^{\alpha }$ is the Riemann–Liouville fractional derivative. By a fixed point theorem in Banach algebra due to Dhage, an existence theorem for fractional hybrid differential equations is proved under mixed Lipschitz and Carathéodory conditions. As an application, examples are presented to illustrate the main results.     

The inverse of nonsymmetric two-level Toeplitz operator matrices

The Gohberg–Semencul formula allows one to express the entries of the inverse of a Toeplitz matrix using only a few entries (the first row and the first column) of the inverse matrix, under some nonsingularity condition. In this paper we will provide a two variable generalization of the Gohberg–Semencul formula in the case of a nonsymmetric two-level Toeplitz matrix with a symbol of the form $f(z_1\text{,}{z}_2)=\frac{1}{\overline{P(z_1\text{,}{z}_2)}Q(z_1\text{,}{z}_2)}$ where $P(z_1\text{,}{z}_2)$ and $Q(z_1\text{,}{z}_2)$ are stable polynomials of two variables. We also consider the case of operator valued two-level Toeplitz matrices. In addition, we propose an equation solver involving two-level Toeplitz matrices. Numerical results are included.     

On the irreducible action of PSL(2,R) on the 3-dimensional Einstein universe

In this paper, we study the irreducible representation of $\text{PSL}(2,\mathbb{R})$ in $\text{PSL}(5,\mathbb{R})$. This action preserves a quadratic form with signature $(2,3)$. Thus, it acts conformally on the 3-dimensional Einstein universe $\mathbb{E}{\mathrm{in}}^{1,2}$. We describe the orbits induced in $\mathbb{E}{\mathrm{in}}^{1,2}$ and its complement in $\mathbb{R}{\mathbb{P}}^4$. This work completes the study in [2], and is one element of the classification of cohomogeneity one actions on $\mathbb{E}{\mathrm{in}}^{1,2}$[5].     

Existence of solution for a fractional advection dispersion equation in RN

This paper is concerned with the existence of solution to the following fractional advection dispersion equation$-{\int }_{|\theta |=1}{D}_{\theta }{D}_{\theta }^{\beta }\mathit{uM}(d\theta )+b(x)u=f(x\text{,}u)\text{,}x\in {\mathbb{R}}^N\text{,}u\in H^{\alpha }({\mathbb{R}}^N)\text{,}$where $N>1\text{,}{\inf }_{{\mathbb{R}}^N}b(x)>0$, $f:{\mathbb{R}}^N\times \mathbb{R}\to \mathbb{R}$ is continuous, the constant $\beta \in (0\text{,}1)\text{,}\alpha =\frac{\beta +1}{2}\text{,}M(d\theta )$ is a Borel probability measure on the unit sphere in ${\mathbb{R}}^N$, $D_{\theta }^{\beta }$ denotes directional fractional derivative of order β in the direction of the unit vector θ. We focus our investigation on the existence of solution to the problem when M is symmetric and nonsymmetric by the Mountain Pass theorem and iterative technique. The main results of this paper emphasize the central role played by the general Borel probability measure.     

Le nombre des diviseurs unitaires d'un entier dans les progressions arithmétiques

Let the functions $d_{k\text{,}l}^{*}(n)$ and $d_{k\text{,}l}(n)$ be number of unitary divisors (see below) and number of divisors n in arithmetic progressions $\{l+mk\}$; k and l are integers relatively prime such that $1?l?k$ and let, for $n?2$

$F(n\text{;}k\text{,}l)=\frac{\ln (d_{k\text{,}l}(n))\ln (\phi (k)\ln n)}{\ln n}\text{,}{F}^{*}(n\text{;}k\text{,}l)=\frac{\ln (d_{k\text{,}l}^{*}(n))\ln (\phi (k)\ln n)}{\ln n}\text{and}$

$D^{*}(n\text{;}k\text{,}l)=\frac{\ln (d_{k\text{,}l}(n)/d_{k\text{,}l}^{*}(n))\ln (\phi (k)\ln n)}{\ln n}\text{,}$

where $\phi (k)$ is Euler's totient. The function $F(n\text{;}k\text{,}l)$ has been studied in [A. Derbal, A. Smati, C. A. Acad. Sci. Paris, Ser. I 339 (2004) 87–90]. In this Note we study the functions $F^{*}(n\text{;}k\text{,}l)$ and $D^{*}(n\text{;}k\text{,}l)$. We give explicitly their maximal orders and we compute effectively the maximum of $F^{*}(n\text{;}k\text{,}l)$ for $k=1\text{,}2\text{,}3$ and that of $D^{*}(n\text{;}k\text{,}l)$ for $k=1\text{,}3\text{,}5\text{,}7\text{,}8\text{,}9\text{,}10\text{,}11\text{,}13$. To cite this article: A. Derbal, C. R. Acad. Sci. Paris, Ser. I 340 (2005).