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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Light scattering of semitransparent media

Li, Qinghe 31 March 2008 (has links)
Polytetrafluoroethylene (PTFE) is a highly scattering material and has been used as diffuse reflectors. In the present study, the ranges of the scattering coefficient, absorption coefficient, and the asymmetric parameter of the Henyey-Greenstein scattering phase function are assessed for semitransparent PTFE films whose thicknesses range from 0.11 mm to 10 mm. The bidirectional reflectance distribution function (BRDF) and bidirectional transmittance distribution function (BTDF) of these PTFE films were measured using a laser scatterometer at a wavelength of 635 nm, and the directional-hemispherical reflectance and transmittance were obtained by integrating BRDF and BTDF at normal incidence. The scattering coefficient of PTFE is estimated to exceed 1200 (1/cm). On the other hand, the absorption coefficient should be less than 0.01 (1/cm). A Monte Carlo simulation was employed to predict the BRDF and BTDF of PTFE films, and the calculations were compared with measurements at various incidence angles.
2

Fusion de données hyperspectrales, polarimétriques et angulaires de diffusion : application au diagnostic optique de milieux denses et complexes / Data fusion system for hyperspectral, polarimetric, and angular scattering : application to optical diagnostic of dense and complex media

Ceolato, Romain 08 November 2013 (has links)
Ces travaux de recherche portent sur le développement d'un système original de fusion de données de diffusion électromagnétique et optique par des milieux denses et complexes. La méthode, à la fois théorique, numérique et expérimentale, permet la fusion des signatures de diffusion hyperspectrales, polarimétriques et angulaires d'un milieu d'étude. Un système expérimental multi-capteurs comprenant une source laser supercontinuum est présenté pour mesurer les signatures de diffusion de différentes cibles. Des modèles directs de simulation physique ont aussi été développés via : (i) une approche dite « top-down » qui modélise les signatures à partir de paramètres macroscopiques (ex. rugosité, indices optiques effectifs) ou (ii) une approche dite « bottom-up » qui modélise les signatures à partir de paramètres microscopiques (ex. distribution en taille, géométrie, concentration, indices optiques et structuration des diffuseurs) en résolvant soit l'équation de transfert radiatif ou directement les équations de Maxwell. Des méthodes inverses appliquées sur les signatures mesurées sont développées pour retrouver simultanément les paramètres d’intérêt du milieu analysé. Les avancées de ces travaux permettent une amélioration de la compréhension des phénomènes de diffusion électromagnétiques et optiques par des milieux denses et complexes tels que les surfaces rugueuses, les revêtements, les nanomatériaux, les suspensions colloïdales ou les agrégats fractals d'aérosols ultrafins. Les domaines d'applications de ces travaux sont l'aéronautique (ex. peintures d'aéronefs), l'imagerie aéroportée ou satellite (ex. imagerie active hyperspectrale ou polarimétrique), la sécurité et la défense (ex. matériaux pour la furtivité) ou bien les sciences de l'atmosphère (ex. systèmes LiDAR, suivi de pollution, suies), l'industrie chimique (ex. suspensions colloïdales) ou le biomédical (ex. diagnostic de tumeurs et mélanomes). / This work reports the development of an original data fusion system dedicated to electromagnetic and light scattering by dense and complex media. The dissertation encompasses the theoretical, numerical and experimental studies. The output of the data fusion system is a fused hyperspectral, polarimetric and angular scattering signature. An experimental multi-sensor and supercontinuum laser-based system is presented to measure the scattering signatures for various targets. Direct physical simulation models were developed using a two-level modelling scheme: (i) a top-down approach is used to model signatures from macro-physical parameters, e.g. the surface roughness or the effective refractive index and, (ii) a bottom-up approach is used to model signatures from microphysical parameters, e.g. the size distribution, the geometry, the concentration, the refractive index and the structuration of the scatterers, by solving the radiative transfer equation or directly the Maxwell's equations. Inversion schemes are deployed to retrieve these parameters by inverting the experimental signatures. The advancements described throughout this dissertation will serve to improve understanding of electromagnetic and light scattering by dense and complex media such as rough surfaces, coatings, nanomaterials, colloidal suspension and fractal aggregates of ultrafine aerosols. This study has relevant applications in fields as diverse as aeronautics (e.g. aircraft paint coatings), remote-sensing (e.g. hyperspectral, polarimetric, active or passive imaging), security and defense (e.g. furtive materials), atmospheric science (e.g. black carbon or soot characterization, LiDAR systems), chemical engineering (e.g. colloidal suspensions), or biomedical (e.g. tumor and melanoma diagnostic).
3

Úprava konstrukce zařízení pro měření rozptylu laserového světla z drsných povrchů / Modification of construction of the device for measuring laser light scattering from rough surfaces

Jaworková, Magdalena January 2020 (has links)
This diploma thesis deals with a design modification of detection part of the laboratory instrument for measuring the topography of rough surfaces – laser goniometric scatterometer (SM II). Design modification is based on replacement of so far used detector instead for the detector of higher quality with better measurement parameters. The first part of the diploma thesis contains theoretical basics, which are necessary to understand the relationship between scalar diffraction theory and scattering measurements of monochromatic light. The emphasis is on the importance of choosing appropriate detection coordinates, which are affecting the aberrations of detected diffracted light. The practical part is dedicated to improving the sensitivity of the detection part of the scatterometer SM II that is used in The laboratory of coherence optics at IFE FME BUT. This part justifies the choice of the detector which predetermines both the use of optical elements and the overall design of the detection part as the goniometer.
4

Development of an Optical Scattering Measurement Device / Produktutveckling av ett optiskt mätinstrument

Grünwald, Ida, Gåhlin, Amanda January 2024 (has links)
Optical scattering measurement devices are used to measure light reflection and light scattering from materials, to obtain data of the surface and bulk properties of materials. The measurement data are often used in research and development projects where material requirements are important, also for quality control in manufacturing processes, in different optical simulations and can be used for photorealistic rendering. In this master thesis project conducted at AFRY, a multifunctional team will develop an optical scattering measurement device that aims to collect data more accurately than current devices on the market. This thesis will focus on the mechanical design of the device which consists of the stability and movement of the components, the environment of the measurements and material selection with a focus on performance and sustainability. The optical model that will act as a basis for the development will be a gonioreflectometer consisting of a material sample, sample holder, light source, detector and an environment in which the measurements are conducted. Some of the physical, cognitive and emotional needs of the intended user are efficient use, low risk of misuse, reliable and high precision. A thorough requirement specification was made as a framework for the concept generation. The selected concept provides the movement of the optical components with an angular step enabling the desired optical scattering measurement. The selected stepper motor and gear ratio provides the flexibility of the movement, making it easy for the user to change angular steps of the optical components, enabling both fine and rough measurements. A separating screen was chosen for both concepts in order to avoid light contamination between measurements and the material sample holder resembles a frame that allows for mounting the material sample outside of the device. The mechanical system has a high stability and the material black anodized aluminum further contributes to the sturdiness of the construction. A physical prototype was created to validate the movement, since the movement of the detector and light source will be similar, only the detector movement was prototyped. The prototype showed that the movement of the detector worked in the desired way, hence the construction of the movement is approved. The scope was delimited in consensus with the project members and supervisors due to the time frame, hence there is future work on the device that should be accounted for. In conclusion, the purpose of the project was fulfilled after delimiting the goals and a conceptual solution was created that fulfilled the requirements of the project. / Optiska mätinstrument används för att mäta ljusreflektion och ljusspridning från material, för att erhålla data om materialets yt- och bulkegenskaper. Mätdata används ofta i forsknings- och utvecklingsprojekt där materialkrav är viktiga, även för kvalitetskontroll i tillverkningsprocesser, i olika optiska simuleringar och kan användas för fotorealistisk rendering. I detta examensarbete, genomfört på AFRY, kommer ett multifunktionellt team att utveckla en optisk spridningsmätningsenhet som syftar till att samla in data mer noggrant. Denna avhandling kommer att fokusera på den mekaniska designen av enheten som består av stabiliteten och rörelsen av komponenterna, mätmiljön och materialval med fokus på prestanda och hållbarhet. Den optiska modellen som kommer att ligga till grund för utvecklingen kommer att vara en gonioreflektometer bestående av ett materialprov, provhållare, ljuskälla, detektor och en miljö där mätningarna genomförs. Några av de fysiska, kognitiva och emotionella behoven hos den avsedda användaren är effektiv användning, låg risk för felanvändning, pålitlighet och hög precision. En noggrann kravspecifikation gjordes som en ram för konceptgenereringen. Det valda konceptet möjliggör rörelse av de optiska komponenterna med ett vinkelsteg som tillåter den önskade optiska spridningsmätningen. Den valda stegmotorn och utväxlingen ger flexibilitet i rörelsen, detta bidrar till att det är enkelt för användaren att ändra vinkelstegen för de optiska komponenterna, vilket tillåter både fina och grova mätningar. En avskiljningsskärm valdes för att undvika ljuskontaminering mellan mätningarna och materialprovhållaren liknar en ram där materialprovet monteras utanför enheten. Det mekaniska systemet har en hög stabilitet och materialet svart anodiserad aluminium bidrar till konstruktionens robusthet. En fysisk prototyp skapades för att validera rörelsen, eftersom rörelsen av detektorn och ljuskällan kommer att vara liknande, återskapades endast detektorns rörelse. Prototypen visade att detektorns rörelse fungerade på önskat sätt, därmed godkänns konstruktionen av rörelsen. Projektets mål avgränsades i samförstånd med projektmedlemmarna och handledarna på grund av tidsramen, därmed finns det framtida arbete för mätinstrumentet som bör beaktas. Sammanfattningsvis uppfylldes projektets syfte efter att målen avgränsats och en konceptuell lösning skapades som uppfyllde projektets krav.

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