Sammanfattning
The main topic of the thesis is the connection between representation theory and special functions. We study matrix elements, coupling coefficient, and recoupling coefficients for the simplest Lie and quantum groups.
We show that a large number of multivariable orthogonal and biorthogonal polynomials occurring in the literature may be obtained as coupling coefficients (generalized ClebschGordan coefficients) for multiple tensor products of highest weight representations of the group SU(1,1). In many cases such polynomials have appeared in applications (physics and statistics), and they are also connected with sperical harmonics. The algebraic interpretation yields a simple and unified approach to the study of these polynomials. The corresponding theory can be developed for the group SU(2) and the oscillator group.
Our original motivation came from ``Hankel theory'', more precisely from the higher order Hankel operators introduced by Svante Janson and Jaak Peetre. The Fourier kernels of such operators are ClebschGordan coefficients, and similarly multivariable coupling coefficients are Fourier kernels of certain multilinear forms. We obtain a Schatten class criterion for these higher order Hankel forms.
We give two new proofs of the triple sum formula for Wigner 9<i>j</i>symbols. These are recoupling coefficients for fourfold tensor products, and appear in the theory of angular momentum in quantum mechanics.
We show that general AskeyWilson and <i>q</i>Racah polynomials arise as matrix elements for the SU(1,1) and SU(2) quantum group, respectively. To obtain this interpretation we introduce some new generalized group elements which include the quantum Weyl element as a degenerate case. We also consider coupling coefficients in the quantum group case. These are multivariable generalizations of the <i>q</i>Racah and AskeyWilson polynomials; however, we focus on the more elementary case of multivariable <i>q</i>Hahn polynomials.
We prove a binomial formula for two variables satisfying a quadratic relation.
We show that a large number of multivariable orthogonal and biorthogonal polynomials occurring in the literature may be obtained as coupling coefficients (generalized ClebschGordan coefficients) for multiple tensor products of highest weight representations of the group SU(1,1). In many cases such polynomials have appeared in applications (physics and statistics), and they are also connected with sperical harmonics. The algebraic interpretation yields a simple and unified approach to the study of these polynomials. The corresponding theory can be developed for the group SU(2) and the oscillator group.
Our original motivation came from ``Hankel theory'', more precisely from the higher order Hankel operators introduced by Svante Janson and Jaak Peetre. The Fourier kernels of such operators are ClebschGordan coefficients, and similarly multivariable coupling coefficients are Fourier kernels of certain multilinear forms. We obtain a Schatten class criterion for these higher order Hankel forms.
We give two new proofs of the triple sum formula for Wigner 9<i>j</i>symbols. These are recoupling coefficients for fourfold tensor products, and appear in the theory of angular momentum in quantum mechanics.
We show that general AskeyWilson and <i>q</i>Racah polynomials arise as matrix elements for the SU(1,1) and SU(2) quantum group, respectively. To obtain this interpretation we introduce some new generalized group elements which include the quantum Weyl element as a degenerate case. We also consider coupling coefficients in the quantum group case. These are multivariable generalizations of the <i>q</i>Racah and AskeyWilson polynomials; however, we focus on the more elementary case of multivariable <i>q</i>Hahn polynomials.
We prove a binomial formula for two variables satisfying a quadratic relation.
Originalspråk  engelska 

Kvalifikation  Doktor 
Tilldelande institution 

Handledare 

Tilldelningsdatum  1999 maj 6 
Förlag  
ISBN (tryckt)  9162835165 
Status  Published  1999 
Bibliografisk information
Defence detailsDate: 19990506
Time: 10:15
Place: Mathematics Building, Sölvegatan 18, Room MH:C
External reviewer(s)
Name: Koornwinder, Tom H
Title: Professor
Affiliation: KdV Instituut, Universiteit van Amsterdam, Netherlands

Ämnesklassifikation (UKÄ)
 Matematik