Refine
Year of publication
- 1998 (109) (remove)
Document Type
- Preprint (109) (remove)
Keywords
- Case Based Reasoning (4)
- CIM-OSA (2)
- Kalman filtering (2)
- TOVE (2)
- coset enumeration (2)
- particle methods (2)
- subgroup problem (2)
- Boltzmann Equation (1)
- Complexity (1)
- Correspondence with other notations (1)
Faculty / Organisational entity
- Kaiserslautern - Fachbereich Mathematik (30)
- Kaiserslautern - Fachbereich Physik (26)
- Kaiserslautern - Fachbereich Informatik (20)
- Fraunhofer (ITWM) (12)
- Kaiserslautern - Fachbereich Wirtschaftswissenschaften (8)
- Kaiserslautern - Fachbereich Elektrotechnik und Informationstechnik (6)
- Kaiserslautern - Fachbereich Maschinenbau und Verfahrenstechnik (6)
- Universitätsbibliothek (1)
Abstract: We develop a constructive method to derive exactly solvable quantum mechanical models of rational (Calogero) and trigonometric (Sutherland) type. This method starts from a linear algebra problem: finding eigenvectors of triangular finite matrices. These eigenvectors are transcribed into eigenfunctions of a selfadjoint Schrödinger operator. We prove the feasibility of our method by constructing an " AG_3 model" of trigonometric type (the rational case was known before from Wolfes 1975). Applying a Coxeter group analysis we prove its equivalence with the B_3 model. In order to better understand features of our construction we exhibit the F_4 rational model with our method.
Verbale Sacherschließung
(1998)
Das Skript gibt eine Einführung in die Geschichte, die Terminologie und die Verfahren der verbalen Sacherschließung. Im deutschsprachigen und englischsprachigen Raum etablierte Verfahren, wie die "Regeln für den Schlagwortkatalog (RSWK)" und die "Library of Congress Subject Headings (LCSH)", werden eingehend beschrieben und Aspekte der Kooperation und Tauglichkeit für Online-Kataloge diskutiert. Charakteristika sowie Vor- und Nachteile der automatischen Indexierung werden anhand des Verfahrens "Maschinelle Indexierung zur verbesserten Literaturerschließung in Online Systemen (MILOS)" dargestellt.
Superselection rules induced by the interaction with the environment are investigated with the help of exactly soluble Hamiltonian models. Starting from the examples of Araki and of Zurek more general models with scattering are presented for which the projection operators onto the induced superselection sectors do no longer commute with the Hamiltonian. The example of an environment given by a free quantum field indicates that infrared divergence plays an essential role for the emergence of induced superselection sectors. For all models the induced superselection sectors are uniquely determined by the Hamiltonian, whereas the time scale of the decoherence depends crucially on the initial state of the total system.
In this paper we derive nonparametric stochastic volatility models in discrete time. These models generalize parametric autoregressive random variance models, which have been applied quite successfully to nancial time series. For the proposed models we investigate nonparametric kernel smoothers. It is seen that so-called nonparametric deconvolution estimators could be applied in this situation and that consistency results known for nonparametric errors- in-variables models carry over to the situation considered herein.
We present a particle method for the numerical simulation of boundary value problems for the steady-state Boltzmann equation. Referring to some recent results concerning steady-state schemes, the current approach may be used for multi-dimensional problems, where the collision scattering kernel is not restricted to Maxwellian molecules. The efficiency of the new approach is demonstrated by some numerical results obtained from simulations for the (two-dimensional) BEnard's instability in a rarefied gas flow.
In this paper we present a domain decomposition approach for the coupling of Boltzmann and Euler equations. Particle methods are used for both equations. This leads to a simple implementation of the coupling procedure and to natural interface conditions between the two domains. Adaptive time and space discretizations and a direct coupling procedure leads to considerable gains in CPU time compared to a solution of the full Boltzmann equation. Several test cases involving a large range of Knudsen numbers are numerically investigated.
Application of Moment Realizability Criteria for Coupling of the Boltzmann and Euler Equations
(1998)
The moment realizability criteria have been used to test the domains of validity of the Boltzmann and Euler Equations. With the help of this criteria teh coupling of the Boltzmann and Euler equations have been performed in two dimensional spatial space. The time evolution of domain decompositions for such equations have been presented in different time steps. The numerical resulta obtained from the coupling code have been compared with those from the pure Boltzmann one.