Global ETD Search

11	Coded Acquisition of High Speed Videos with Multiple Cameras Pournaghi, Reza 10 April 2015 (has links) High frame rate video (HFV) is an important investigational tool in sciences, engineering and military. In ultrahigh speed imaging, the obtainable temporal, spatial and spectral resolutions are limited by the sustainable throughput of in-camera mass memory, the lower bound of exposure time, and illumination conditions. In order to break these bottlenecks, we propose a new coded video acquisition framework that employs K>1 cameras, each of which makes random measurements of the video signal in both temporal and spatial domains. For each of the K cameras, this multi-camera strategy greatly relaxes the stringent requirements in memory speed, shutter speed, and illumination strength. The recovery of HFV from these random measurements is posed and solved as a large scale l1 minimization problem by exploiting joint temporal and spatial sparsities of the 3D signal. Three coded video acquisition techniques of varied trade o s between performance and hardware complexity are developed: frame-wise coded acquisition, pixel-wise coded acquisition, and column-row-wise coded acquisition. The performances of these techniques are analyzed in relation to the sparsity of the underlying video signal. To make ultra high speed cameras of coded exposure more practical and a fordable, we develop a coded exposure video/image acquisition system by an innovative assembling of multiple rolling shutter cameras. Each of the constituent rolling shutter cameras adopts a random pixel read-out mechanism by simply changing the read out order of pixel rows from sequential to random. Simulations of these new image/video coded acquisition techniques are carried out and experimental results are reported. / Dissertation / Doctor of Philosophy (PhD) Compressive Sensing High Speed Video Coded Acquisition Random Sampling Sparse Representation Digital Cameras Rolling Shutter
12	A New Pool Boiling Facility for the Study of Nanofluids Strack, James M. 04 1900 (has links) <p>Nanofluids are engineered colloidal dispersions of nanoparticles in a liquid. The field of nanofluids has seen much interest due to reported heat transfer enhancements over the corresponding pure fluids at low particle concentrations. Particularly, a large increase in critical heat flux (CHF) has been widely reported along with modification of the boiling interface. Inconsistencies in reported impact on nucleate boiling heat transfer and the degree of CHF enhancement illustrate the need for further study.</p> <p>A pool boiling experiment has been designed and constructed at McMaster University to allow for the study the boiling of water-based nanofluids. The facility has been commissioned with saturated distilled water tests at atmospheric pressure, heat flux levels up to 1200 kW·m<sup>-2</sup>, and at wall superheat levels up to 19.5<sup>o</sup>C. Wall superheat and heat flux uncertainties were estimated to be ±0.6<sup>o</sup>C and ±20 kW∙m<sup>-2</sup>, respectively. For the installed test section, heat flux is limited to 2.62 ± 0.06 MW·m<sup>-2</sup>. A high speed video system for the analysis of bubble dynamics was tested and used for qualitative comparisons between experimental runs. This system was tested at 2500 FPS and an imaging resolution of 39 pixels per mm, but is capable of up to 10 000 FPS at the same spatial resolution. Heat flux versus wall superheat data was compared to the Rohsenow correlation and found to qualitatively agree using surface factor <em>C<sub>sf</sub></em> = 0.011. Results were found to have a high degree of repeatability at heat flux levels higher than 600 kW·m<sup>-2</sup>.</p> <p>The new facility will be used to conduct studies into the pool boiling of saturated water-based nanofluids at atmospheric pressure. Additional work will involve the control and characterization of heater surface conditions before and after boiling. Quantitative analysis of bubble dynamics will be possible using high speed video and particle image velocimetry.</p> / Master of Applied Science (MASc) Heat Transfer, Combustion Heat Transfer, Combustion
13	Development of High Speed High Dynamic Range Videography Griffiths, David John 09 February 2017 (has links) High speed video has been a significant tool for unraveling the quantitative and qualitative assessment of phenomena that is too fast to readily observe. It was first used in 1852 by William Henry Fox Talbot to settle a dispute with reference to the synchronous position of a horse's hooves while galloping. Since that time private industry, government, and enthusiasts have been measuring dynamic scenarios with high speed video. One challenge that faces the high speed video community is the dynamic range of the sensors. The dynamic range of the sensor is constrained to the bit depth of the analog to digital converter, the deep well capacity of the sensor site, and baseline noise. A typical high speed camera can span a 60 dB dynamic range, 1000:1, natively. More recently the dynamic range has been extended to about 80 dB utilizing different pixel acquisition methods. In this dissertation a method to extend the dynamic range will be presented and demonstrated to extend the dynamic range of a high speed camera system to over 170 dB, about 31,000,000:1. The proposed formation methodology is adaptable to any camera combination, and almost any needed dynamic range. The dramatic increase in the dynamic range is made possible through an adaptation of the current high dynamic range image formation methodologies. Due to the high cost of a high speed camera, a minimum number of cameras are desired to form a high dynamic range high speed video system. With a reduced number of cameras spanning a significant range, the errors on the formation process compound significantly relative to a normal high dynamic range image. The increase in uncertainty is created from the lack of relevant correlated information for final image formation, necessitating the development of a new formation methodology. In the proceeding text the problem statement and background information will be reviewed in depth. The development of a new weighting function, stochastic image formation process, tone map methodology, and optimized multi camera design will be presented. The proposed methodologies' effectiveness will be compared to current methods throughout the text and a final demonstration will be presented. / Ph. D. High Dynamic Range Video High Speed Video HDR image HDRI tone map
14	Experimental Assessment of Charge Flow in Electrospinning Stanger, Jonathan Jeffrey January 2013 (has links) Electrospinning is a method of using high voltage electric fields to transform polymer solutions into nano-scale fibres. The field has seen significant work on processing different polymers and their resulting fibres but less work has focused the electrospinning process itself. The aim of this thesis is to present experimental observations of charge behaviour in the electrospinning process in the context of the underlying physics typically used to describe electrospinning. This thesis presents a review of existing methods of measuring aspects of the electrospinning process, and reviews published mathematical models of the process as representative examples of the current understanding of the underlying physics that drive the electrospinning phenomena. A novel measurement technique is introduced - high frequency data capture of the electric current flow simultaneously at the high voltage and collector electrode. This is used in three ways: to examine bulk charge density, to measure fibre flight time, and to quantify charge lost from the fibre in flight. Charge density is studied by comparing current and mass flow at the Taylor cone under a wide range of conditions. For 8% PVOH in water a constant bulk charge density was found of 7.7 C/kg. Flight time is studied by determining the time from the application of high voltage to the charged fibre first arriving at the collector electrode. It was found that for 8% PVOH the flight time depended strongly on applied voltage while electrode distance had a negligible effect. Charge loss was studied by comparing the magnitude of the simultaneous current flows in the quasi-steady state to determine if the charge flowing into the Taylor cone arrives with the fibre at the collector. For 8% PVOH, 8% PVOH with ionic salt, 9% PVOH in water and 18% PVB in ethanol, it was found that charge is always lost. electrospinning charge density charge loss electric current flight time high speed video mass deposition rate computational fluid dynamics simulation
15	Impact resistance of high strength fiber reinforced concrete Zhang, Lihe 05 1900 (has links) Concrete structures may be subjected to dynamic loading during their service life. Understanding the dynamic properties of concrete structures is becoming critical because of the increased concern about the dynamic loading of both civilian and military structures, and especially, the recent increase in terrorist attacks on structures. Fiber reinforced concrete (FRC) is known to exhibit superior performance in its post-peak energy absorption capacity, (i.e., toughness) under flexural and tensile loading. However, the behavior of fiber reinforced concrete under compressive impact has not previously been investigated. In the present research, the response of fiber reinforced concrete was investigated over the full strain rate regime, from static loading to high strain rate loading, and finally to impact loading. The compressive toughness of FRC under static loading was studied using an existing Japanese standard (JSCE SF-5). Then, a test method for FRC under compressive impact loading was developed, involving the use of a high speed video camera system to measure the deformation of FRC cylinders under compressive impact. The strain rate sensitivity of FRC in both flexure and compression was also fully investigated. FRC was found to have higher strengths under impact loading (both flexural and compressive) than under static loading. The compressive toughness under impact loading increased due to the high peak load and the high strain capacity. FRC under flexural impact loading showed a greater strength improvement than under static flexure. FRC displays a much higher Dynamic Improvement Factor (DIF) under flexural impact than under compressive impact. It gave an overall higher performance under impact than under static loading. It also exhibited a higher strain rate sensitivity than plain concrete in both compression and flexure. Damage analysis, in terms of loss of strain energy, was carried out based on damage mechanics principles. Damage was found to increase with increasing strain rate. A new constitutive model was proposed to account for the relationship between DIF (Comp) and strain rate and the data derived from the model were found to be consistent with the experimental results. Impact resistance Fiber reinforced concrete High strength Compressive toughness High speed video Flexural toughness Damage analysis Strain rate
16	Impact resistance of high strength fiber reinforced concrete Zhang, Lihe 05 1900 (has links) Concrete structures may be subjected to dynamic loading during their service life. Understanding the dynamic properties of concrete structures is becoming critical because of the increased concern about the dynamic loading of both civilian and military structures, and especially, the recent increase in terrorist attacks on structures. Fiber reinforced concrete (FRC) is known to exhibit superior performance in its post-peak energy absorption capacity, (i.e., toughness) under flexural and tensile loading. However, the behavior of fiber reinforced concrete under compressive impact has not previously been investigated. In the present research, the response of fiber reinforced concrete was investigated over the full strain rate regime, from static loading to high strain rate loading, and finally to impact loading. The compressive toughness of FRC under static loading was studied using an existing Japanese standard (JSCE SF-5). Then, a test method for FRC under compressive impact loading was developed, involving the use of a high speed video camera system to measure the deformation of FRC cylinders under compressive impact. The strain rate sensitivity of FRC in both flexure and compression was also fully investigated. FRC was found to have higher strengths under impact loading (both flexural and compressive) than under static loading. The compressive toughness under impact loading increased due to the high peak load and the high strain capacity. FRC under flexural impact loading showed a greater strength improvement than under static flexure. FRC displays a much higher Dynamic Improvement Factor (DIF) under flexural impact than under compressive impact. It gave an overall higher performance under impact than under static loading. It also exhibited a higher strain rate sensitivity than plain concrete in both compression and flexure. Damage analysis, in terms of loss of strain energy, was carried out based on damage mechanics principles. Damage was found to increase with increasing strain rate. A new constitutive model was proposed to account for the relationship between DIF (Comp) and strain rate and the data derived from the model were found to be consistent with the experimental results. Impact resistance Fiber reinforced concrete High strength Compressive toughness High speed video Flexural toughness Damage analysis Strain rate
17	Impact resistance of high strength fiber reinforced concrete Zhang, Lihe 05 1900 (has links) Concrete structures may be subjected to dynamic loading during their service life. Understanding the dynamic properties of concrete structures is becoming critical because of the increased concern about the dynamic loading of both civilian and military structures, and especially, the recent increase in terrorist attacks on structures. Fiber reinforced concrete (FRC) is known to exhibit superior performance in its post-peak energy absorption capacity, (i.e., toughness) under flexural and tensile loading. However, the behavior of fiber reinforced concrete under compressive impact has not previously been investigated. In the present research, the response of fiber reinforced concrete was investigated over the full strain rate regime, from static loading to high strain rate loading, and finally to impact loading. The compressive toughness of FRC under static loading was studied using an existing Japanese standard (JSCE SF-5). Then, a test method for FRC under compressive impact loading was developed, involving the use of a high speed video camera system to measure the deformation of FRC cylinders under compressive impact. The strain rate sensitivity of FRC in both flexure and compression was also fully investigated. FRC was found to have higher strengths under impact loading (both flexural and compressive) than under static loading. The compressive toughness under impact loading increased due to the high peak load and the high strain capacity. FRC under flexural impact loading showed a greater strength improvement than under static flexure. FRC displays a much higher Dynamic Improvement Factor (DIF) under flexural impact than under compressive impact. It gave an overall higher performance under impact than under static loading. It also exhibited a higher strain rate sensitivity than plain concrete in both compression and flexure. Damage analysis, in terms of loss of strain energy, was carried out based on damage mechanics principles. Damage was found to increase with increasing strain rate. A new constitutive model was proposed to account for the relationship between DIF (Comp) and strain rate and the data derived from the model were found to be consistent with the experimental results. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate Impact resistance Fiber reinforced concrete High strength Compressive toughness High speed video Flexural toughness Damage analysis Strain rate
18	Exploring Capabilities of Electrical Capacitance Tomography Sensor & Velocity Analysis of Two-Phase R-134a Flow Through a Sudden Expansion Cronin, Joseph M. 09 June 2017 (has links) No description available. Mechanical Engineering two-phase flow high speed video analysis electrical capacitance tomography sudden expansion velocity analysis R-134a
19	Étude théorique et expérimentale d’une torche plasma triphasée à arcs libres associée à un procédé de gazéification de matière organique / Theoretical and experimental studies of arcs in a three phase plasma torch coupled to a gasification process of organic matter Rehmet, Christophe 24 September 2013 (has links) Les torches à arcs plasma sont actuellement utilisées dans de nombreuses applications industrielles. Une technologie plasma triphasée à électrodes en graphite est en cours de développement au Centre PERSEE MINES ParisTech. Cette technologie diffère sensiblement des technologies à courant continu traditionnelles et vise à dépasser certaines limites des systèmes actuels en termes de robustesse, de coûts d'équipement et d'exploitation pour des applications liées à conversion et la valorisation de biomasse et déchets. Dans le but d'améliorer la compréhension des phénomènes physiques instationnaires intervenant dans les décharges triphasées, une étude menée en parallèle sur les plans théorique et expérimental a été conduite en conditions non réactives (azote et gaz de synthèse). Sur un plan expérimental cette étude s'est appuyée sur des analyses réalisées avec une caméra ultra rapide (100 000 images par seconde) et l'analyse des signaux électriques. Sur un plan théorique cette étude a consisté à développer un modèle Magnéto-Hydro-Dynamique (MHD) 3D instationnaire de la zone d'arc dans l'environnement du logiciel Code Saturne® et à effectuer une étude paramétrique basée sur le courant, la fréquence et le débit de gaz plasma. Deux configurations : électrodes coplanaires et parallèles ont été étudiées. Cette étude a permis de mettre en avant l'influence des phénomènes électromagnétiques et hydrodynamiques sur le déplacement de l'arc. Dans le cas coplanaire les jets aux électrodes semblent jouer un rôle prépondérant sur le mouvement des arcs, les transferts de chaleur dans l'espace inter électrode et l'amorçage des arcs. Dans le cas parallèle le mouvement des canaux chauds semble être le paramètre dominant. La confrontation des résultats théoriques et expérimentaux a montré un très bon accord à la fois au niveau du mouvement des arcs et des signaux électriques. / Arc plasma torches are widely used in industrial applications. A 3-phase AC plasma technology with consumable graphite electrodes is under development at PERSEE MINES - ParisTech. This technology noticeably differs from the classical DC plasma torches and aims at overcoming a number of limits of plasma systems in terms of reliability, equipment and operating costs. In order to improve the understanding of the unsteady physical phenomena in such plasma systems, a theoretical and experimental study is conducted under non reactive condition (nitrogen, syngas). Experimental study is based on high speed video camera (100 000 frames per second) and electrical signal analyses. Theoretical analysis is based on 3D unsteady Magneto-Hydro-Dynamic (MHD) model of the arc zone using CFD software Code_Saturne®, by a parametric study based on current, frequency and plasma gas flow rate influence. Two configurations: coplanar and parallel electrodes are studied. These studies highlight the influence of electromagnetic and hydrodynamic phenomena on the arc motion. In coplanar electrode configuration, electrode jets appear to be the dominant parameter on the arc motion, heat transfer and arc ignition. In the parallel electrodes configuration, the motion of the hot channel seems to be the key parameter. Comparison between MHD modeling and experimental results shows a fair correlation, both in accordance with the arc behavior and the electrical waveform. Plasma triphasé MagnetoHydrodynamique Arc électrique instationnaire Camera rapide 3-phase Ac plasma torch MagnetoHydrodynamic Electrical arc behavior High speed video camera
20	Přídavný paměťový modul pro vysokorychlostní kameru / Extended memory module for the high-speed camera Trtílek, Jakub January 2017 (has links) Goal of the diploma thesis is a design of fast memory module and to introduce myself with issues involved in data storage in memory of high speed camera. The work is concerned about two designs adding memory capacity of high speed camera with DDR3 memory modules. For production is selected the more suitable design that is better for commercial purposes. The main objective is to design a schematic with FPGA as a main controller, that will operate data flow from CMOS sensor to superior development board MicroZed. Final design should allow us to sell the high speed camera as a separate unit.

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