Two and three dimensional cephalometric assessment of dental and skeletal changes following orthodontic treatment with Damon passive self-ligating system

Ehsani, Sayeh

06 1900

Objectives: The aim of this study was to evaluate dental and/or skeletal changes following orthodontic treatment with Damon self-ligating (SL) brackets in non-extraction patients. Methods: Frontal and lateral cephalomteric radiographs of 20 patients before and after non-extraction treatment with Damon SL brackets were analyzed in a three-dimensional analysis computer program (3DCeph, UIC, IL., USA). Changes of intermolar and intercanine distances, incisor positions and maxillary basal bone width of Damon treated subjects were compared to corresponding untreated controls (Bolton templates). Comparisons between the two groups were made with Nonparametric (Mann-Whitney U) test. Results and Conclusions: Transverse changes in distances between crowns of upper and lower first molars and canines in Damon group were similar to untreated individuals (P >0.01). However, in Damon group distances between roots of upper molars and lower canines increased 4.59 and 3.49 mm respectively, compared with 0.8 and -0.01 mm in the Control group (P <0.001, P= 0.001). Lingual root torque of upper incisors and proclination of lower incisors were larger in the Damon group (P<0.05). Damon treatment did not result in buccal tipping of molar crowns or maxillary base width increase (P>0.05). Overall, teeth alignment with Damon system was accomplished with a combination of arch width changes and incisor proclination and/or lingual root torque.

Orthodontic brackets

Self-ligating

Three-dimensional cephalometrics

Dental arch width

Verification of 3-D biomechanical model joint angle outputs using a computer generated avatar

Westfall, Brad J.

January 1900

Thesis (M.S.)--West Virginia University, 2006. / Title from document title page. Document formatted into pages; contains vii, 124 p. : ill. (some col.). Includes abstract. Includes bibliographical references (p. 76).

Real-time visualization of massive imagery and volumetric datasets

Roth, Ian Joseph.

January 2006

Thesis (M.S.)--University of Missouri-Columbia, 2006. / The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Title from title screen of research.pdf file viewed on (February 23, 2006) Includes bibliographical references.

Towards automatic oracles for the testing of mesh simplification software

Ho, Chun-fai, Jeffrey.

January 2005

Thesis (M. Phil.)--University of Hong Kong, 2006. / Title proper from title frame. Also available in printed format.

An evaluation of 3D-GIS as a public engagement tool in environmental impact assessment

Kwong, Kim-hung.

January 2006

Thesis (M. Phil.)--University of Hong Kong, 2006. / Title proper from title frame. Also available in printed format.

Extended three-dimensional ADCIRC hydrodynamic model to include baroclinic flow and sediment transport

Pandoe, Wahyu Widodo

30 September 2004

The objective of this research is to identify the circulation patterns of the water and sediment fluxes in coastal and estuarine zones, where the shoaling processes correlate with tide generating flow patterns. The research provides a better understanding of the characteristics of spatial and temporal variability of currents. An important deviation from previous research is the inclusion of the baroclinic term, which becomes very important in density driven flows. The understanding of this process provides a basis for determining how the water circulation three-dimensionally controls the hydrodynamics of the system and ultimately transports the suspended and soluble materials due to combined currents and waves. A three-dimensional circulation model is used to calculate the water circulation. The model is based on the three-dimensional (3D) version of Advanced Circulation (AD-CIRC) Hydrodynamic Model with extending the Sediment Transport module. The model is based on the finite element method on unstructured grids. The output of the hydrody-namic model is used to estimate spatial and temporal advections, dispersions and bottom shear stress for the erosion, suspension, deposition and transport of sediment. The model development includes extending the existing three-dimensional (3D) ADCIRC Model with (1) baroclinic forcing term and (2) transport module of suspended and soluble materials. The transport module covers the erosion, material suspension and deposition processes for both cohesive and non-cohesive type sediments. The inclusion of the baroclinic demonstrates the potential of over or underpredicting the total net transport of suspended cohesive sediment under influence of currents. The model provides less than 6% error of theoretical mass conservation for eroded, suspended and deposited sediment material. The inclusion of the baroclinic term in stratified water demonstrates the prevailing longshore sediment transport. It is shown that the model has an application to the transport of the cohesive sediments from the mouth of the Mississippi River along the north shore of the Gulf of Mexico towards and along the Texas coast. The model is also applicable to determine the design erosion thickness of a cap for isolating contaminated dredged material and to evaluate the appro-priate grain size of cap sediments to minimize the erosion.

Three-dimensional hydrodynamic

finite telement

baroclinic

sediment transport

ADCIRC.

Free Form Incident Light Fields

Unger, Jonas, Gustavson, Stefan, Per, Larsson, Ynnerman, Anders

January 2008

This paper presents methods for photo-realistic rendering using strongly spatially variant illumination captured from real scenes. The illumination is captured along arbitrary paths in space using a high dynamic range, HDR, video camera system with position tracking. Light samples are rearranged into 4-D incident light fields (ILF) suitable for direct use as illumination in renderings. Analysis of the captured data allows for estimation of the shape, position and spatial and angular properties of light sources in the scene. The estimated light sources can be extracted from the large 4D data set and handled separately to render scenes more efficiently and with higher quality. The ILF lighting can also be edited for detailed artistic control.

Three-Dimensional Graphics and Realism

Digitization and Image Capture

TECHNOLOGY

TEKNIKVETENSKAP

Three-dimensional analysis of airflow and temperature in a thyristor valve hall

Berg, Jeffrey R

10 April 2006

A numerical analysis is performed for the three-dimensional, turbulent flow of air in a thyristor valve hall located at the Dorsey Converter Station, owned and operated by Manitoba Hydro. The goal of this analysis was to determine the configurations that result in increased air-side cooling effectiveness in the valve hall. The governing equations are solved using the Computational Fluid Dynamics (CFD) code CFX-5. This computer code uses a finite volume method of solution and is based on a finite element approach for representing the geometry. The effects of inlet and outlet opening geometry, inlet air mass flow rate, and inlet air angle on the thermal performance for the air-side cooling of the thyristor valve hall geometry are examined. / May 2006

heated blocks

three-dimensional

simulation

thyristor

turbulent

heated obstacles

Modeling of Simultaneous Switching Noise in On-Chip and Package Power Distribution Networks Using Conformal Mapping, Finite Difference Time Domain and Cavity Resonator Methods

Mao, Jifeng

29 October 2004

This thesis focused on modeling and simulation of simultaneous switching noise in packages as well as integrated circuits and the focus was mainly on the latter. Efficient and accurate methods have been developed for modeling the coupling due to SSN in multi-layered planes arising in electronic packages, extraction of the power grid in integrated circuits and simulation of the power supply noise in large size networks arising in power distribution network. These methods include conformal mapping, finite difference time domain and cavity resonator methods, using which the electrical performance of the power distribution system in a high speed electronic product can be predicted. The model developed for field penetration captured the effect of the magnetic field penetrating through planes in multi-layered packages. Analytical model for the extraction of the interconnect parasitics for a regular on-chip power grid has been presented. Complex image technique has been applied for modeling the dispersive interconnect on lossy silicon substrate. The Debye rational approximation has been used to approximate the RLGC parameters in order to simulate the frequency dependent elements in the time domain. The simulation of the entire network of the full-chip power grid has been carried out using the modified FDTD expressions. Several aspects of characterizing the generic on-chip power distribution network have been presented. The crossover capacitance has been evaluated using analytical model derived from conformal mapping. An analytical model has been proposed to extract parameters of on-chip multi-conductor transmission lines, which guarantees the stability and is applicable to general distribution of multi-conductor transmission lines. The above modeling procedures have been incorporated into a computer program, which generates the power grid model from the layout of chip power distribution networks automatically. Research on 3-D on-chip power distribution networks has been presented. The complex image technique has been extended from microstrip-type interconnects to stripline-type interconnects. Macromodel images have been derived with closed form expressions to capture the loss mechanism of the multiple conductive substrates. The effect of 3-D integration on switching noise has been illustrated in the time domain using examples.

Field penetration

Power grid

Lossy substrate

Three dimensional integrated circuits

Distribution of Stress in Three-Dimensional Models of Human Coronary Atherosclerotic Plaque Based on Acrylic Histologic Sections

Lowder, Margaret Loraine

05 June 2007

Each year in the United States over a million people experience a myocardial infarction. The majority of these attacks are caused by coronary artery plaque cap rupture with subsequent thrombus formation. Because rupture is a mechanical event and the tendency of a plaque to rupture is due in part to increases in the mechanical stresses in the fibrous cap, mechanical analyses are important to understanding plaque stability. Histology is the only method capable of identifying plaque features that are associated with vulnerability. Therefore, minimally distorted histologic sections should serve as a basis for constructing the models used in mechanical analyses. Further, because substantial longitudinal variations in geometry and mechanical properties often exist, models should be three-dimensional (3-D). Finally, given the complex geometries of atherosclerotic plaques and the fact that they are composed of different materials, the finite element (FE) method should be used to determine the distribution of stress under physiological loading. Until now, a critical need has existed to determine the distribution of stress in 3-D FE models of human coronary atherosclerotic plaques based on minimally distorted histologic sections. In this research study, a method to measure and correct for distortions caused by acrylic histologic processing was first created. The devised strain-based method yields a limited set of parameters needed for a first order correction. Thus, corrections can be easily implemented using FE methods. Next, a methodology to create 3-D finite FE models of human coronary atherosclerotic plaques based on stable acrylic histologic sections was developed. Models of plaques, ranging in disease severity, were generated using the developed methodology. Lastly, the distributions of stress in these models were obtained and the effects of some plaque features on stresses were determined. Results from this study confirm that morphological description of a plaque is not sufficient to predict plaque rupture. The findings suggest that in many cases the 3-D stress field within a plaque must be known in order to assess plaque stability. Finally, the results show that patient specific models must be developed if the 3-D stress field within a plaque is to be determined.

Histology

Coronary artery

Finite element model

Atherosclerosis

Three-dimensional reconstruction