QUANTITATIVE FTIR IMAGING FOR CONTACT DYNAMICS ANALYSIS

sun, mengyue

04 December 2022

No description available.

Polymers

Materials Science

Fluid Dynamics

Investigation and application of the Frustrated-Total-Internal-Reflection phenomenon in optical fibers

Rahnavardy, Kambiz

07 November 2008

All-fiber optical sensors have established themselves in the market for a decade. Among different categories of these sensors is the intensity-based type whose advantages make it suitable for many practical applications. Frustrated Total Internal Reflection (FTIR) is a phenomenon that shows a great potential to be used as a transduction mechanism in this type of sensors. Although physical interpretation of the phenomenon itself is rather complicated, it can be mathematically formulated in a non-extensive manner. The first attempt is to build a physical understanding of the phenomenon as well as a simple mathematical model based on planar waves. Then, it will be expanded it to waves inside a waveguide structure like optical fibers in a concrete way based on computer simulations and actual experiments, a task that has never been done before. This would make it possible to address the practical issues involved afterwards. Again, the obtained experimental results as well as simulations help analyze advantages and disadvantages of our basic structure and move on to design a practically viable all-fiber FTIR sensor. A prototype vacuum pressure sensor has been designed and tested to show the potential in this category of optical sensors. Some other applications are also briefly discussed to give us a good feeling of the restrictive problems and future prospective of the ongoing related research. / Master of Science

Frustrated Total Internal Reflection

FTIR

optical fibers

fiber optics

sensors

LD5655.V855 1996.R346

Sensor de força utilizando Fiber taper / Fiber taper based force sensor

Hernandez, Felipe Bueno

29 March 2016

Este trabalho teve por objetivo desenvolver e caracterizar um sensor de força utilizando uma fibra óptica modificada pelo processo conhecido como Fiber tapering. A fibra quando modificada deixa exposto o campo evanescente, o que a torna sensível a influências externas, e a luz guiada na fibra pode vir a sofrer reflexão interna total frustrada ao entrar em contato com materiais. Ao envolver a região modificada por um material elastomérico, a área de contato e consequentemente a atenuação torna-se uma função da intensidade da força aplicada, possibilitando então relacionar a força a atenuação da luz. Baseando-se nesse efeito, foi criado um sensor de dimensões reduzidas, de rápida resposta, linear, altamente sensível e de boa repetibilidade. Foi criado também um circuito eletrônico utilizando amplificadores operacionais para a aquisição e processamento do sinal proveniente da fibra e selecionado um sensor comercial comum para a realização de experimentos e comparações. Ambos os sensores foram posicionados sobre uma balança de precisão e submetidos a diversos esforços obtendo-se dados sobre a resposta estática. Em seguida utilizando um shaker eletrodinâmico foram medidos os tempos de resposta a uma entrada degrau, e realizando esforços repetitivos foram analisados os desvios das medidas lidas pelos sensores. / The aim of this research was to develop and characterize a force sensor using a modified optical fiber by a process known as Fiber tapering. The modified fiber leaves the evanescent field exposed and prone to external influences and the guided light may suffer frustration of total internal reflection upon contact with materials. When covering the modified fiber section with an elastomeric material, the contact area and therefore the attenuation becomes a function of the applied pressure, making it possible to relate force to attenuation in light intensity. Based on this effect, a small sensor was created, having a quick response time, with high linearity, high sensitivity and good repeatability. Along with the sensor, an electronic circuit using operational amplifiers was designed for acquisition and processing of the signal obtained from the optical fiber. In addition, in order to perform experiments and comparisons, a standard force sensor was chosen. Both sensors were placed over a precision weighing scale and had different intensities of force applied on them, and after that, data regarding static measurements was gathered. The response time was obtained using an electrodynamic shaker and applying a step input. Furthermore, data was gathered about the deviations on the measurements by performing a repetitive set of compressions.

Fiber taper

Envanescent wave

Fiber taper

Force sensor

Frustrated total internal reflection

Onda evanescente

Optical fiber sensor

Reflexão interna total frustrada

Sensor de fibra óptica

Sensor de força

Cristaux photoniques à gradient : dispositifs et applications / Graded Photonic Crystals : devices and applications

Gaufillet, Fabian

12 November 2014

Les matériaux artificiellement structurés que sont les cristaux photoniques sont couramment utilisés pour leurs propriétés dispersives. Leur constante diélectrique varie périodiquement à l'échelle de la longueur d'onde selon deux ou trois directions avec un contraste d'indice suffisamment élevé. La relation de dispersion ω = ω(k) qui résulte de cette variation périodique a la forme d'une structure de bande à l'intérieur de laquelle il existe des bandes interdites photoniques où la propagation du champ électromagnétique est interdite. En dehors de ces bandes, i.e. dans les bandes photoniques, se trouvent les propriétés de dispersion des cristaux photoniques.Le but de ce travail de thèse est de concevoir, de fabriquer et de caractériser des dispositifs à cristal photonique à gradient. Ces dispositifs ont été conçus de façon à s'appliquer dans les domaines allant des micro-ondes à l'optique. Nous avons conçu des dispositifs à partir de cristaux photoniques dont les propriétés dispersives les rendent analogues à des milieux linéaires, homogènes et isotropes (LHI). À la maille élémentaire de ces cristaux photoniques LHI, nous avons appliqué un gradient pour réaliser des lentilles à gradient 1D. Des résultats importants concernant la conception, la fabrication et la caractérisation expérimentale d'une lentille plate à gradient d'indice fonctionnant dans la bande X des micro-ondes sont reportés. Celle lentille focalise une onde plane incidente et collimate l'onde émise par une source ponctuelle situés dans son plan focal. Si cette lentille constitue en soi un démonstrateur et valide la démarche mise en œuvre pour la concevoir, ses applications potentielles concernent particulièrement les antennes. Nous réalisons également plusieurs lentilles à gradient 2D dont des lentilles de Lüneburg et Half Maxwell Fisheye; leurs applications aux antennes sont importantes. Nous nous intéressons aussi à la réalisation de lentilles optiques à gradient d'indice dites « SELFOC® ». Dans le but de confirmer les propriétés dispersives remarquables qui ont été mises en évidence, nous avons poursuivi dans ce sens en revisitant une expérience classique qui met en évidence l'existence des ondes évanescentes : celle du « double prisme à angle droit ». Nous mettons également en évidence le phénomène de « réflexion totale frustrée » ainsi que le décalage, découvert par Goos et Hänchen, que subit l'onde réfléchie sur le dioptre. Ce sont ces deux points — réflexion totale frustrée et effet Goos-Hänchen — que nous vérifions dans le cas de cristaux photoniques LHI. / Artificially structured materials that are photonic crystals are commonly used for their dispersive properties. Their dielectric constant varies periodically across the wavelength in two or three directions with a sufficiently high index contrast. The resulting dispersion relation ω = ω(k) of the periodic variation has the form of a band structure within which there are photonic bandgaps in which the propagation of the electromagnetic field is prohibited. Outside of these bands, i.e. in the photonic band, there are the dispersion properties of the photonic crystals.The aim of this thesis is to design, fabricate and characterize graded photonic crystal devices. These devices were designed to be applied in areas ranging from microwaves to optics. We designed devices from photonic crystals with dispersive properties which make them similar to linear, homogeneous and isotropic media (LHI). In the unit cell of the LHI photonic crystal, we applied a gradient to achieve 1D graded lenses. Important results regarding the design, manufacturing and experimental characterization of a flat lens GRIN operating in X-band microwaves are deferred. This lens focuses an incident plane wave and collimates the wave emitted by a point source located in its focal plane. If this lens is itself a demonstrator and validates the approach implemented for the design, its potential applications particularly concern antennas. We also carry several 2D graded lenses including Lüneburg and Half Maxwell Fisheye lenses; their applications to the antennas are important. We are also interested in making optical graded index lenses called "SELFOC®".In order to confirm the remarkable dispersive properties that have been identified, we continued in that direction by revisiting a classic experiment that highlights the existence of evanescent waves: the "double right angle prism". We also highlight the phenomenon of "frustrated total internal reflection" and the shift discovered by Goos and Hänchen suffered by the reflected wave on the interface. It's these two points – frustrated total internal reflection and Goos-Hänchen effect - that we check in the case of LHI photonic crystals.

Cristaux photoniques à gradient

Gradient d'indice

Lentille

FDTD

Réflexion totale frustrée

Graded Photonic Crystals

Graded index

Lens

FDTD

Frustrated total internal reflection

Sensor de força utilizando Fiber taper / Fiber taper based force sensor

Felipe Bueno Hernandez

29 March 2016

Este trabalho teve por objetivo desenvolver e caracterizar um sensor de força utilizando uma fibra óptica modificada pelo processo conhecido como Fiber tapering. A fibra quando modificada deixa exposto o campo evanescente, o que a torna sensível a influências externas, e a luz guiada na fibra pode vir a sofrer reflexão interna total frustrada ao entrar em contato com materiais. Ao envolver a região modificada por um material elastomérico, a área de contato e consequentemente a atenuação torna-se uma função da intensidade da força aplicada, possibilitando então relacionar a força a atenuação da luz. Baseando-se nesse efeito, foi criado um sensor de dimensões reduzidas, de rápida resposta, linear, altamente sensível e de boa repetibilidade. Foi criado também um circuito eletrônico utilizando amplificadores operacionais para a aquisição e processamento do sinal proveniente da fibra e selecionado um sensor comercial comum para a realização de experimentos e comparações. Ambos os sensores foram posicionados sobre uma balança de precisão e submetidos a diversos esforços obtendo-se dados sobre a resposta estática. Em seguida utilizando um shaker eletrodinâmico foram medidos os tempos de resposta a uma entrada degrau, e realizando esforços repetitivos foram analisados os desvios das medidas lidas pelos sensores. / The aim of this research was to develop and characterize a force sensor using a modified optical fiber by a process known as Fiber tapering. The modified fiber leaves the evanescent field exposed and prone to external influences and the guided light may suffer frustration of total internal reflection upon contact with materials. When covering the modified fiber section with an elastomeric material, the contact area and therefore the attenuation becomes a function of the applied pressure, making it possible to relate force to attenuation in light intensity. Based on this effect, a small sensor was created, having a quick response time, with high linearity, high sensitivity and good repeatability. Along with the sensor, an electronic circuit using operational amplifiers was designed for acquisition and processing of the signal obtained from the optical fiber. In addition, in order to perform experiments and comparisons, a standard force sensor was chosen. Both sensors were placed over a precision weighing scale and had different intensities of force applied on them, and after that, data regarding static measurements was gathered. The response time was obtained using an electrodynamic shaker and applying a step input. Furthermore, data was gathered about the deviations on the measurements by performing a repetitive set of compressions.

Fiber taper

Onda evanescente

Reflexão interna total frustrada

Sensor de fibra óptica

Sensor de força

Envanescent wave

Fiber taper

Force sensor

Frustrated total internal reflection

Optical fiber sensor