Statistische Analyse von Verkehrsdaten und die Modellierung von Verkehrsfluss mittels zellularer Automaten - Statistical Analysis of Traffic Data and Modelling of Traffic Flow using Cellular Automata

Neubert, Lutz

22 May 2001

Past and recent investigations of traffic dynamics mostly rest on averaged data taken over a short period of time, e.g. one minute. They make a qualitative distinction between the generally accepted traffic states called "free flow", "synchronised flow" and "Stop-and-Go traffic" possible. However, the essential car-car-interactions on the microscopic level are concealed. With extensive statistical examinations of single-vehicle traffic data presented in this work one gains new insights especially from a microscopic point of view. By means of time series analyses, correlation functions and by use of histogram methods new evaluation methods for driving behaviour are introduced. These quantities show a strong dependency on the present traffic state, the observed interval of density and the environment (e.g., freeway or city traffic). Microscopic features like synchronisation of velocities ranging over a number of vehicles or decreasing time headways smaller than one second noticeably influence macroscopic proper ties of traffic as expressed in fundamental diagrams. Moreover, on the basis of cross correlation functions connecting flow and density some quantities can be defined to discriminate between the several traffic states quantitatively. These empirical results have impacts on modelling and simulation of traffic flow. A modified cellular automaton comprising aspects of anticipation is introduced and discussed in great detail. Metastable states can be formed and all other criteria are also met to indicate a well-operating traffic flow model. A lot of simulations were done in order to analyse single-lane and multi-lane behaviour and to find out the specific problems coming along with event-driven measuremens methods using "inductive loops". Another focus are density waves to estimate their speed and to elucidate the phase separation and the transition between different traffic states.

Molekulardynamik-Simulationen von strukturellen Phasenumwandlungen in Festkörpern, Nanopartikeln und ultradünnen Filmen - Molecular-dynamics simulations of structural phase-transitions in bulk, nanoparticles, and ultra-thin films

Kadau, Kai

25 May 2001

In this work structural properties of bulk, nano-particles, and thin films were investigated by using molecular-dynamics simulations. The focus was on the investigation of martensitic transformations in those systems, mainly consisted of Fe and Ni. For the describtion of the interatomic forces the Embedded-Atom Method was used. The calculation of the free energy as a function of temperature gave insight into the thermodynamics of the system, and led to a correct interpretation of the structural transformation from a closed packed structure (face-centered-cubic, hexagonal-closed-packed) to the body-centered-cubic structure and vice versa. Pre-existing lattice defects turned out to be the dominant factor for the martensitic transformation at low temperatures, whereby the austenitic transformation at high temperatures is less affected by defects. The explanation of the different behavior of the martensitc transformation process and the austenitic transformation process could be given by a detailed examination of the free energy along the Bain-path. The study of the crystallographic orientational relationships of the austenitic and martensitic phases gave insight into the transformation process on the atomic-scale. The transformation process observed in the molecular-dynamics simulations can be described in terms of the Wechsler-Lieberman-Read theory as a combination of Bain-transformation, rotation, and lattice invariant shear due to stacking faults and twinning. Simulations of very large supercells containing up to eight million atoms facilitated the study of the homogeneous and heterogeneus nucleation process of structural phase transitions within the solid state. Molecular-dynamics simulations of shock-induced austenitic transformations gave valueable insight into the grain-boundary dynamics of the developing austenitic grains. The heterogeneous nucleation process at different types of defects in nano-particles was studied. The burst-type growth of the martensitc phase starts at pre-existing defects with further growth of the twinned martensitic phase into the austenite-matrix. With decreasing size of the nano-particle, transition temperatures decreased as revealed in the few experiments that exist. In the framework of the used Embedded-Atom Method-potential, this effect is due to the different surface energies of the austenitic and the martensitic phases. The interplay between the structure of films and an underlying substrate was intensively studied for the well known Fe on Cu-system. Experimental observations, like the increasing tendency for a structural transformation from the face-centered-cubic structure to the body-centered-cubic structure with increasing film thickness and decreasing temperature, were confirmed. Simulations of the growth process gave insight into recently performed experiments of the dependence of the structural stability of face-centered-cubic Fe-films on Cu(111)-substrates as a function of the deposition process like thermal deposition and pulsed laser deposition.

Einfluß von Strukturstörungen auf die optischen und elektronischen Eigenschaften von borreichen Festkörpern mit Ikosaederstruktur - Influence of structure defects on optical and electronic properties of icosahedral boron rich solids

Schmechel, Roland

01 June 2001

Boron and boron rich solids are known to have a high concentration on intrinsic structural imperfections. From known structure data of real crystals and known band structure calculations of perfect ideal crystals a correlation between intrinsic structure defect concentration and electron deficit in the valence band is concluded. This correlation forms the basis for the following theses: 1. The electron deficit in the valence band of a perfect crystal is the driving force for the intrinsic structure defects in a real crystal. 2. The small electron deficit becomes compensated by the structure defects - this explains the semiconducting behavior. 3. The structure defects are the reason for the high density of localized electronic states in the band gap. The photoluminescence of beta-rhombohedral boron in the range 0.75eV to 1.4eV under interband excitation was investigated systematically and was interpreted using the one-dimensional Franck-Conden-Model. The only partially occupied B13-position in beta-rhombohedra l boron is suggested to be the reason for the localized electronic state, which is involved in the photoluminescence process. Together with an investigation of the time-depending photoconductivity under interband excitation the energy band schema of beta-rhombohedral boron is improved. The improved energy band schema is able to explain all known experimental data including the fatiguing of photoluminescence. An investigation of FIR-spectra of boron carbide and metal doped beta-rhombohedral boron by Kramers-Kronig-Analysis gives information on the main transport processes. Beside hopping conduction of localized electrons, band conduction of delocalized electrons were found. While holes in the valence band are the delocalized charge carriers in boron carbide, in vanadium doped beta-rhombohedral boron delocalized electrons in an extrinsic impurity band are suggested

Theory and Application of Advanced Traffic Forecast Methods / Neue Methoden der Verkehrsprognose: Theorie und Praxis

Chrobok, Roland

20 July 2005

The work deals with the task of forecasting motorway traffic states. The data of inductive loop detectors, placed on a large scale German motorway network, are analysed in regard to develop new traffic forecast algorithms. An application is presented that uses the new algorithms in operation for online traffic information.

Ladungsträgerquantisierung in selbstorganisierten Nanostrukturen / Charge quantisation in self-assembled nanostructures

Wibbelhoff, Oliver

07 August 2006

This work presents an analysis of the energy structure of carriers enclosed in self-assembled InAs quantum dots. Capacitance-voltage-spectroscopy (CV) with perpendicular magnetic fields is used to identify the energy structure of holes in quantum dots. Applying a two-dimensional harmonic oscillator model, we demonstrate an irregular filling sequence where the d states are occupied with holes before the filling of the p shell is completed. This surprising behavior is explained by a shift in the energy structure in favor of the coulomb repulsion due to the strong interaction in the hole system. We have mapped out the wave functions of electron and hole carriers using CV-spectroscopy with parallel magnetic fields. This allows us to obtain two dimensional plots of the probability densities in k-space for the carriers. The wave functions are interpreted in a quasi particle picture. For the s electrons in quantum dots we obtain Gaussian like probability densities with certain deviations. The wave functions are elongated along [1-10] in direct space. This is caused by a morphological anisotropy of the quantum dots and due to the piezoelectric effect in these structures. The p states show nodal structures with orbitals that are oriented perpendicular to each other. The low energy p states are oriented along [1-10] in direct space. The hole wave functions show an elongation along the perpendicular direction [110] in direct space. This confirms the assumption that the probability distribution is mainly influenced by piezoelectric effects in the strained semiconductor system. Using polarization dependent photoluminescence spectroscopy we demonstrate an energy shift in the interband transitions which indicates an anisotropic confining potential.

Synchronized traffic: microscopic modeling and empirical observations <br>Synchronisierter Verkehr: mikroskopische Modellierung und empirische Beobachtungen

Knospe, Wolfgang

27 August 2002

A detailed analysis of single-vehicle data is presented that sheds some light on the microscopic interaction of the vehicles in the various traffic states. Based on these results an improved cellular automaton model for traffic flow incorporating anticipation effects, reduced acceleration capabilities and an enhanced interaction horizon for braking is proposed. The model is able to reproduce the three phases (free flow, synchronized traffic, and wide jams) observed in real traffic. Furthermore a good agreement with detailed empirical single-vehicle data in all phases can be found. It turns out, that the incorporation of the human desire for smooth and comfortable driving into the driving strategy of vehicles leads to a model that exhibits synchronized traffic. Anticipation effects are responsible for a stabilization of the traffic phases and the empirically observed coexistence of wide moving jams with both free flow and synchronized traffic can be reproduced. It is shown that the single-lane dynamics can be extended to the two-lane case without changing the basic (realistic) properties of the model. Therefore it is possible to reproduce special two-lane phenomena, like the synchronization of the lanes, the lane usage inversion and the density-dependence of the number of lane changes, without adapting the parameters of the model. Finally, a statistical analysis of traffic data that is provided by an area-wide coverage of the highway network of North Rhine-Westfalia with inductive loops is given. The identification and characterization of the bottlenecks of the network reveal that the bottlenecks are not of topological nature but are constituted by onramps. This underscores the applicability of ramp metering systems.

Der Einfluss thermoplastischer Elastomere auf die Struktur und das Kristallisationsverhalten von Polyolefin-Blends

Plawky, Udo

10 September 2001

Seit einigen Jahren gewinnt die Forschung an mehrkomponentigen heterogenen Polymersystemen zunehmend Bedeutung. Dies liegt neben dem akademischen Forschungsinteresse auch an dem grossen wirtschaftlichen Interesse in der industriellen Anwendung. In der Materialforschung werden aufgrund des gestiegenen Bedarfs an vielseitigen und preisgüunstigen Hochleistungswerkstoffen mit einem breiten Eigenschaftsprofil neue Polymerwerkstoffe durch Mischung vorhandener Homopolymere entwickelt. Von großer industrieller Bedeutung ist die Kombination der beiden Polymere isotaktisches Polypropylen (iPP) und Polyethylen (PE). In diesen Systemen wird iPP und PE in bestimmten Gewichtsverhältnissen gemischt, um die Eigenschaften des Werkstoffs gezielt zu verändern. Die Verbesserungen des Eigenschaftsprofils werden häufig als das Resultat synergetischer Effekte zwischen den jeweiligen Komponenten des Systems erklärt. Jedoch stellt das Polymersystem iPP/PE innerhalb des gesamten Konzentrationsbereichs ein nichtmischbares Polymersystem dar. Die resultierenden neuen Materialeigenschaften des Systems iPP/PE erreichen deshalb oft nicht das geforderte Eigenschaftsprofil. Aufgrund der Nichtmischbarkeit kommt es zu einer Phasenseparation. Diese führt u.a. zu einer inhomogenen Verteilung der Minorphase in der Matrix. Die schlechte Adhäsion an den Phasengrenzen beeinträchtigt die Kraftübertragung bei Belastung des Materials und beeinflußt so die mechanischen Eigenschaften des Systems. Eine Moeglichkeit, diese aus der Nichtmischbarkeit der Ausgangskomponenten resultierenden Nachteile zu vermeiden, besteht in dem Einsatz von grenzflaechenaktiven Polymeren, sogenannten Vertraeglichkeitsmachern Haeufig werden sogenannte Block- oder Pfropf-Copolymere als Vertraeglichkeitsmacher eingesetzt. Sie sollen in der Phasengrenze der nichtmischbaren Polymere derart lokalisiert sein, dass sie die Grenzphase ueberbruecken. Eine Vielzahl von Untersuchungen wurde durchgefuehrt, um fuer spezielle Polymersysteme die passenden Vertraeglichkeitsmacher zu entwickeln.

Numerische Untersuchungen von Gleichgewichts- und Nichtgleichgewichtseigenschaften verdünnter Antiferromagnete - Numerical investigations of equilibrium and non-equilibrium properties of diluted antiferromagnets

Staats, Michael

12 September 2001

Magnetic models with strong disorder are the topic of this work. Diluted antiferromagnets in an external field (DAFF) are of special interest, both from a theoretical, and from an experimental point of view. In this work critical exponents at various points in the temperature vs. magnetic field phase diagram are determined by the analysis of exact calculated ground states and of Monte Carlo simulations. The specific heat and its critical exponent deserve special attention. Simulations of irreversibilities of the specific heat are in agreement with latest measurements. Further emphasis is put on the investigation of the non-equilibrium dynamics of the DAFF. The relaxation dynamics of the DAFF is governed by thermal activation. Further it is shown that also the DAFF exhibits Aging effects, as they are known from many other disordered systems

Diffusionsinduzierte Brechungsindexänderungen in Polymerfilmen als Funktionsprinzip optischer Chemosensoren - Optical chemo-sensors based on diffusion induced refractive index changes in polymer films

Podgorsek, Robert-Philip

13 September 2001

In this thesis several polymer materials have been investigated with respect to their application as optical chemo-sensors, which are based on molecule diffusion into thin sensitive layers. The dynamic response of such sensors is mainly controlled by the diffusion kinetics of the molecules in the film. The solution of the diffusion differential equation (2nd Ficks law) in the case of thin films yields the temporary concentration profile of the molecules in the film. Linearity between the refractive index changes and the concentration follows directly from the Lorentz-Lorenz equation and therefore gives the same variation for the index changes. With that the development of the refractive index profile during in- and out-diffusion is well described by the diffusion theory and consequently the dynamic response of the optical sensor can be modelled by a suitable theory. Thin glass/silver/polymer multilayer systems have been characterised with respect to their optical sensing parameters by using metal film enhanced leaky mode spectroscopy. This useful optical technique, which offers the observation of the surface plasmon resonance and the leaky modes of thin dielectric films, has been improved for the analysis of inhomogeneous refractive index profiles by using a transfer-matrix formalism for layered media. Furthermore, waveguide birefringence experiments on thin anisotropic polyimide films as planar lightguides have been carried out to show how the sensitivity of the sensor can be optimised by a suitable choice or a specific modification of the polymer material.

Temperaturabhängigkeit magnetischer Anisotropien in ultradünnen Filmen - Temperature dependence of magnetic anisotropies in ultra-thin films

Hucht, Alfred

13 September 2001

Anisotropies essentially affect magnetism in thin ferromagnetic films of few atomic layers. On the one hand they can stabilize long range order in these systems, on the other hand they strongly influence the orientation of magnetization. The intrinsic causes of anisotropies in these systems are the spin-orbit coupling of the electrons and the long-range magnetic dipole interaction. While the dipole interaction always favors an orientation of magnetization in the plane of the film, spin-orbit coupling can favor different orientations of magnetization on the surface and in the inner layers of the film. This can lead to a competition between anisotropies, which in turn leads to a spin reorientation transition with varying film thickness. This transition can be of varying order, i. e. be continuous or discontinuous. Experiments also find a spin reorientation transition with varying temperature, which until now was not well understood. In the framework of a classical Heisenberg model this transition is investigate d by means of different theoretical methods in the course of this thesis. At zero temperature the system can be dealt with analytically and criteria for the spin reorientation transition and its order are found. Furthermore it is investigated whether the long-range dipole interaction results in a domain ground state. These investigations are extended to finite temperatures by means of a molecular field theory and results are compared to Monte Carlo simulations. It is shown that in contrast to other works the temperature driven spin reorientation transition in the monolayer is discontinuous also in the simulations, whereas in general it is continuous for the bilayer. Consequently the molecular field theory and the Monte Carlo simulations agree qualitatively. Exemplary for thicker films the influence of an external magnetic field is investigated in the bilayer, furthermore the effective anisotropies Kn(T) of the phenomenological Landau theory are calculated numerically for the microscopic model. Analytic expres sions for the dependence of the anisotropies Kn(T) on the parameters of the model are obtained by the means of perturbation theory, which lead to a deeper understanding of the spin reorientation transition. Accordingly to this the origin for the spin reorientation transition lies in the differing temperature dependence of the dipolar and spin-orbit parts of the Kn(T). Additionally the magnetization in the surface of the film decreases more rapidly with increasing temperature. As a consequence the influence of the surface anisotropy decreases with increasing temperature. This effects a similar result as increasing the film thickness and leads to the transition. Finally the model is extended to continuous film thicknesses, since in experiment the spin reorientation transition depends crucially on film thickness. The results of this extended model are compared to experiment and give good agreement.