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- Hideyuki Ishi
- Analysis on regular convex cones associated to decomposable graphs
- Regular convex cones of positive definite real symmetric matrices with
prescribed zero entries
have been studied intensively in multivariate statistics. It turned
out that analysis on the cone is quite
feasible if the zero pattern corresponds to a decomposable graph.
Indeed, an explicit formula is known
for the Fourier-Laplace transform of a product of powers of minors
over the cone. Inspired by these statistic works,
we develop analysis on the cone in a similar way to theory of
homogeneous cones. In particular, we consider
Riesz distributions on the cone and associated b-functions.
- Yumiko Hironaka
- Spherical functions on certain $p$-adic homogeneous spaces, and some
relation to PV-theory
- First I want to introduce a typical spherical function on certain
homogeneous space $X$, and give its expression formula by using
functional equations of sph. f's and data of the group. In this talk
everything is assumed to be defined over a $\mathfrak{p}$-adic field $k$.
Typical sph. f's are obtained by Poisson transform from relative
$P$-invariant on $X$, where $P$ is a minimal parabolic that has Zarisky
open orbit in $X$ over $\overline{k}$, and their functional equations
are often reduced to those for certain limited type of prehomogeneous
vector spaces.
Then I want to discuss about some spaces of sesquiliear forms, and give
explicit formulas of sph.f's by using specialized Hall-Littlewood
polynomials associated to the root system, parametrization of all the
sph.f's, and Plancherel formula.
(The latter half is joint work with Y. Komori.)
- Koichi Takase
- On spherical functions of supercuspidal representations of $GL_n(F)$ and prehomogeneous vector spaces over finite fields
- We will consider the spherical function of a square-integrable irreducible representation of $G$ with respect to a $K$-type with a compact subgroup $K$ of $G$, and want to determine the non-zero set of the Fourier transform of the spherical function. In the case of the holomorphic discrete series, there exists a close relationship between the non-zero set and a pre homogeneous vector space of parabolic type associated with a boundary component of $G/K$. We can consider a parallel problem for $p$-adic reductive group. In this talk, I will report on the result of an experiment for the simplest case of an irreducible level-zero super cuspidal representation of $GL_n(F)$.
- Jean-Louis Clerc
- Conformally invariant trilinear forms on the sphere
- Given three scalar principal series representations of the conformal group of the sphere, I will first recall the construction of the (essentially unique) invariant trilinear form in the generic case. I will then discuss the singular cases.
- Salah Mehdi
- Representation theoretic differential operators
- We will discuss several results on representations of Lie groups
related to invariant differential operators on homogeneous spaces,
with an emphasis on Dirac operators. If time allows, we will also present
some connections between Dirac operators and coherent families of modules.
- Pascale Harinck
- Fourier transform of the Schwartz space of a $p$-adic reductive symmetric space
- Let $X=H\backslash G$ be a $p$-adic reductive symmetric space over a non archimedean local field $\mathbb F$ of characteristic different from $2$. An explicit Plancherel formula for $L^2(X)$ (spectral decomposition) was recently described when $G$ is split and $\mathbb F$ of characteristic zero by Y.Sakellaridis and A.Venkatesh, and for general $G$ and $\mathbb F$ of characteristic different from $2$ by P. Delorme.
In this talk, I will explain a joint work with Y.Sakellaridis and P.Delorme in which we describe the Fourier transform on the Harish-Chandra Schwartz space of $X$. We obtain a spectral decomposition of this space. Our proof uses the strong version of the Plancherel formula and properties of Eisenstein integrals and their weak constant term.
- Robert J. Stanton
- Extensions on real bounded symmetric domains
- The real bounded symmetric domains were classified by H. Jaffee as the fixed point sets of anti-holomorphic involutions of bounded symmetric domains in $\Bbb C^n$ (there are now several alternative descriptions). B. Krötz and I showed how the harmonic analysis on the real domain has a holomorphic continuation and determined the extent of this. In this talk we will re-visit this setting from the point of view of split complex structures. We will show the existence of a split holomorphic domain containing the real domain and we will show the existence of split holomorphic extensions of the harmonic analysis to this domain. This is joint work with G.Ólafsson.
- Marcus J. Slupinski
- Symplectic goemetry of spinors in $12$-dimensions
- The spinor representations of the double cover of the orthogonal group in twelve dimensions are regular prehomogeneous vector spaces and in 1970 J-I. Igusa gave a normal form for each orbit and determined the corresponding isotropy groups. These representations each carry an invariant symplectic form and their direct sum is a Clifford module. In this talk we give a new classification of the orbits and describe the geometry of each orbit (over a field of characteristic not two or three) in terms of symplectic covariants and properties with respect to Clifford multiplication. This is joint work with R.J.Stanton.
- Fumihiro Sato
- Automorphic pairs of distributions on prehomogeneous vector spaces and zeta functions
- Kyo NISHIYAMA (AGU)
- Robinson-Schensted-type correspondence over mirabolic double flag variety
- We consider the conormal variety (or the Steinberg variety) over a mirabolic double flag variety for a symmetric pair $ (G, K) $.
If the double flag variety has finitely many $ K $-orbits, the irreducible components of the conormal variety $ Y $ encode the parametrization of orbits.
On the other hand, if we consider the image of a moment map called an exotic nilpotent cone, nilpotent $ K $-orbits together with its fiber (an analogue of Springer fiber) also classifies irreducible components of $ Y $. Thus we get a correspondence between geometric parametrization of orbits and the parametrization given by nilpotent orbits and its fiber. This is what we call "Robinson-Schensted-type correspondence".
It turns out this whole picture is strongly related to the exotic (or enhanced) nilpotent cone, which are studied by many people including Travkin, Syu Kato, Achar-Henderson, Henderson-Trapa and Shoji-Sorlin among others.
We will discuss the RS-type correspondence as well as the structure of the exotic nilpotent cone for the symmetric pair of type AIII.
This is an on-going joint work with Lucas Fresse.