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The Post-Weld-Shift Measurement of Butterfly-Type Laser Module Packaging by Capacitance Displacememt SystemHu, Feng-ruei 24 July 2007 (has links)
A novel technique by employing a capacitance displacement measurement system to measure the post-weld-shift (PWS) caused by laser welding in the butterfly-type laser diode module packaging process is proposed. Reduction of the PWS is an important issue in developing low-cost and high-performance semiconductor laser module. Prior to the reduction and compensation of the PWS, a measurement system of PWS must be constructed.
In comparison to the high-magnification camera with image capturing system (HMCICS) limited in resolution of 0.07£gm due to its pixels, a measurement system with a higher resolution of 0.0254£gm is used. During the measurement procedure, the PWS of the ferrule probed by the sensors is converted into the fiber misalignment shifts. The coupling efficiency can be improved over 70% after compensation. The result indicates that the PWS can be qualitatively measured and quantitatively computed.
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Design and Optimization of Displacement Measurement Eddy Current Sensor for Mass ProductionGuganeswaran, S January 2014 (has links) (PDF)
Eddy current (EC) based testing and measurement methods are well known in non-destructive testing (NDT) world. EC sensors are extensively studied and used for material health monitoring and its property measurement. Target displacement measurement is one of the well-known applications of EC method. The main advantage of EC sensor is its working capability in harsh environment like humidity, contamination etc. It is non-contact, rugged and requires less maintenance. The range and sensitivity of target displacement is mainly determined by the probe geometry and its construction method. Also displacement measurement depends upon geometry and electromagnetic (EM) properties of the target plate. Any variation of ambient temperature alters the EM properties of the probe as well as EM properties of the target. Thus, many parameters like geometry, EM properties and temperature involved in target displacement measurement. Hence, while using EC sensor for displacement measurement, it demands careful design and measurement procedure to achieve high sensitivity and high precision with low temperature drift. To achieve these, we present the following. 1) A temperature compensation technique 2) Optimization of probe geometry and its construction method to increase the range and sensitivity 3) Selection of suitable probe measurement parameter (Z, R, X) based on target material properties 4) Making the displacement measurement less sensitive to tolerance in probe construction parameter.
A temperature compensation technique for target displacement measurement, using a self-running LC oscillator has been presented. A sensing coil is energized by a Hartley oscillator. The oscillator voltage is maintained at a constant level by a closed loop feedback circuit and the average feedback current to the oscillator is measured for target displacement detection. The temperature drift of the feedback current is compensated by applying temperature compensation function (TCF) and this is verified experimentally. Cold rolled mild steel (carbon steel) is taken as a target material and the sensor is tested over a temperature range of 20 °C – 80 °C. It shows that the temperature drift is less than ±30 ppm/°C over 3 mm target displacement. To match all the sensor modules in mass production, components selection procedure is presented. To avoid mismatch across sensors in manufacturing process, the transistor based oscillator is modified with operational trans-conductance amplifier (OTA). The same temperature compensation formula (TCF) is applied to compensate the temperature drift of feedback current and achieved intended accuracy.
Geometry and construction parameters of the eddy current sensing probe is optimized for target displacement measurement using Ansoft Maxwell, electromagnetic design software. EC probe with
different geometry are analyzed in search of suitable geometry for target displacement measurement. Four shapes of commercially available core have been chosen for probe construction. For each shape of sensing probe, the radius and height of the probe is increased by 0 mm to 9 mm to find the effect of them on sensitivity and range of target displacement measurement. It has been observed that the probe with less height and maximum diameter has shown better performance. In addition to that, the probe geometry is optimized to achieve more sensitivity and range within the space available for probe mounting. It helps to utilize the available space effectively for probe design. Coil winding and mount-ing it inside the core window also important parameter in probe design. It has been observed that de-pressing the sensing coil inside the core window from sensing face by 3 mm decreases the sensitivity by 40 %. Hence, it is recommended to place the coil on the extreme end of the sensing face of the core. To know the effect of core permeability, it is varied from 1000 to 15000. It has been observed that it has no effect on sensitivity and measurement range.
Only optimizing the probe geometry and its construction method is not adequate for target displacement measurement. We know that the EC based displacement measurement is also target material dependent. Generally probe impedance is measured and then the temperature drift of the sensing coil resistance is compensated to know the target displacement. Most of the temperature compensation techniques use this compensation technique and it is shown that those are suitable for high conductivity targets like copper. Choosing Z for displacement measurement may not be only best choice for all target materials. The displacement can be measured also through either R or X of the probe. Choosing the proper probe parameter for a given target material will provide a less temperature drift for target displacement measurement. To know about this, a simulation has been made for target displacement measurement with target metal of μr = 1, relative permittivity εr =1, and temperature coefficient of resistivity ∝ = 0.004 K-1. The conductivity (σ) of the target is varied from 1×106 S/m to 62×106 S/m in the temperature range of 20 ℃ – 80 ℃. Now the simulation has been repeated by fixing as a constant and varying target μr. The metal plate with = 1×106 S/m, εr=1 and ∝ = 0.004 K – 1 is taken as a target and μr is varied from 100 to 10000. For both conductivity and permeability sweep analysis, the target displacement is measured as a function of Z, R and X independently. The temperature drift in displacement measurement is also analysed for the above temperature range. An experiment has been conducted with copper, stainless steel and mild steel as target metal in the temperature range of 20 ℃ – 80 ℃. The temperature drift is calculated when the displacement is measured as function of Z, R and X. Based on the results, we have identified that the target material relative permeability determines the selection of probe measurement parameter for target displacement measurement. Hence, knowing tar-get r alone suffice to select the probe measurement parameter (Z or R or X) for displacement measurement.
Optimizing the probe geometry, selecting the proper probe measurement parameter and temperature compensation technique suffice to provide a good sensitivity, range and low temperature drift for
a single probe. But in general, one of the mass produced probes is selected as a reference probe and it is calibrated against the ambient temperature and target displacement. And the calibration curves are loaded to all the probes. Matching the probe construction parameters to each other across the production patches is not possible in mass production. This makes the temperature compensation function and displacement calibration are different for every individual probes for displacement measurement. This degrades the measurement accuracy. A simulation has been performed with pot core with commercial tolerance. Using this, we have obtained 24 probes due to variations in 1) Individual and few combinational variations in core and coil dimensions 2) Core permeability variation and 3) relative position of the coil with respect to core. Finally, we have quantified the displacement error for each probe. We have identified the important probe dimensional parameters that have to be controlled precisely in mass production to improve the measurement accuracy. It shows error of 0.86 % in the displacement measurement when the relative reactance and relative displacement is used for measurement.
In practice, error in displacement measurement due to both the ambient temperature drift and the tolerance in probe construction parameter exist simultaneously. Hence, the combined error is computed for the target displacement range of 0 mm – 3 mm for the temperature range of 0 °C – 100 °C. The total error of less than 1 % is achieved for commercial standard probe tolerance. Finally, we have provided general factory production procedure and user calibration procedure of probe design to achieve cost effective displacement measurement with sensitivity and range with low temperature drift.
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Millimeter-wave sensorsKim, Seoktae 12 April 2006 (has links)
New millimeter wave interferometric, multifunctional sensors have been studied for
industrial sensing applications: displacement measurement, liquid-level gauging and
velocimetry. Two types of configuration were investigated to implement the sensor:
homodyne and double-channel homodyne. Both sensors were integrated on planar
structure using MMIC (Microwave Monolithic Integrated Circuit) and MIC (Microwave
Integrated Circuit) technology for light, compact, and low-cost design. The displacement
measurement results employing homodyne configuration show that sub-millimeter
resolution in the order of 0.05 mm is feasible without correcting the non-linear phase
response of the quadrature mixer.
The double-channel homodyne configuration is proposed to suppress the nonlinearity
of the quadrature mixer and to estimate the effect of frequency stability of a
microwave signal source without the help of additional test equipment, at the loss of a
slight increase of circuit complexity. The digital quadrature mixer is constituted by a
quadrature-sampling signal processing technique and takes an important role in the
elimination of conventional quadrature mixer's nonlinear phase response. Also, in the
same displacement measurement, the radar sensor with the double-channel homodyne
configuration provided a better resolution of 0.01mm, the best-reported resolution to
date in terms of wavelength in the millimeter wave range, than the sensor employing
simple homodyne configuration.
Short-term stability of a microwave signal source, which is an important issue in
phase sensitive measurement, is also considered through phase noise spectrum obtained
by FFT spectral estimator at Intermediate Frequency (IF).
The developed sensors demonstrate that displacement sensing with micron
resolution and accuracy and high-resolution low-velocity measurement are feasible using
millimeter-wave interferometer, which is attractive not only for displacement and
velocity measurement, but also for other industrial sensing applications requiring very
fine resolution and accuracy.
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Contribuição ao desenvolvimento de transdutores indutivos de deslocamentoMotta, Eduardo Costa da January 2002 (has links)
O presente trabalho enfoca o estudo de transdutores indutivos de deslocamento linear. Dentre os diversos dispositivos dessa natureza, procurou-se desenvolver um estudo mais aprofundado do transdutor indutivo diferencial com núcleo de esferas. O desenvolvimento experimental, com a construção de quatro protótipos, levou ao projeto de um transdutor com características adequadas ao uso industrial. / The present work focuses on the study of inductive transducers of linear displacement. Among the several devices of that nature, a more detailed study of the inductive differential transducer was attempted with core of spherical balls. The experimental development of four prototypes resulted in a transducer with characteristics adequate for industrial use to be designed.
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Fusion de mesures de déplacement issues d'imagerie SAR : application aux modélisations séismo-volcaniques / Fusion of displacement measurements from SAR imagery : application to seismo-volcanic modelingYan, Yajing 08 December 2011 (has links)
Suite aux lancements successifs de satellites pour l'observation de la Terre dotés de capteur SAR (Synthetic Aperture Radar), la masse de données SAR disponible est considérable. Dans ce contexte, la fusion des mesures de déplacement issues de l'imagerie SAR est prometteuse à la fois dans la communauté de la télédétection et dans le domaine géophysique. Dans cette optique, cette thèse propose d'élargir les approches conventionnelles en combinant les techniques de traitement des images SAR, les méthodes de fusion d'informations et la connaissance géophysique. Dans un premier temps, cette thèse a pour objectif d'étudier plusieurs stratégies de fusion, l'inversion jointe, la pré-fusion et la post-fusion, afin de réduire l'incertitude associée d'une part à l'estimation du déplacement en 3 dimensions (3D) à la surface de la Terre, d'autre part à la modélisation physique qui décrit la source en profondeur du déplacement observé en surface. Nous évaluons les avantages et les inconvénients de chacune des stratégies en ce qui concerne la réduction de l'incertitude et la robustesse vis à vis du bruit. Dans un second temps, nous visons à prendre en compte les incertitudes épistémiques, en plus des incertitudes aléatoires, présentes dans les mesures et proposons les approches classiques et floues basées sur la théorie des probabilités et la théorie des possibilités pour modéliser ces incertitudes. Nous analysons et mettons en évidence l'efficacité de chaque approche dans le cadre de chaque stratégie de fusion. La première application consiste à estimer les champs du déplacement 3D à la surface de la Terre dus au séisme du Cachemire en octobre 2005 et à l'éruption du Piton de la Fournaise en janvier 2004 sur l'île de la Réunion. La deuxième application porte sur la modélisation de la rupture de la faille en profondeur liée au séisme du Cachemire. Les principales avancées sont évaluées d'un point de vue méthodologique en traitement de l'information et d'un point de vue géophysique. Au niveau méthodologique, afin de lever les principales difficultées rencontrées pour l'application de l'interférométrie différentielle à la mesure du déplacement induit par le séisme du Cachemire, une stratégie de multi-échelles basée sur l'information a priori en utilisant les fréquences locales de phase interférométrique est adoptée avec succès. En ce qui concerne la gestion de l'incertitude, les incertitudes aléatoires et épistémiques sont analysées et identifiées dans les mesures du déplacement. La théorie des probabilités et la théorie des possibilités sont utilisées afin de modéliser et de gérer les propagations des incertitudes au cours de la fusion. En outre, les comparaisons entre les distributions de possibilité enrichissent les comparaisons faites simplement entre les valeurs et indiquent la pertinence des distributions de possibilité dans le contexte étudié. Par ailleurs, la pré-fusion et la post-fusion, 2 stratégies de fusion différentes de la stratégie d'inversion jointe couramment utilisée, sont proposées afin de réduire autant que possible les incertitudes hétérogènes présentes en pratique dans les mesures et pour contourner les principales limitations de la stratégie d'inversion jointe. Les bons cadres d'application de chaque approche de la gestion de l'incertitude sont mis en évidence dans le contexte de ces stratégies de fusion. Au niveau géophysique, l'application de l'interférométrie différentielle à l'étude du séisme du Cachemire est réalisée pour la première fois et compléte les études antérieures basées sur les mesures issues de la corrélation des images SAR et optiques, les mesures télésismiques et les mesures de terrain. L'interférométrie différentielle apporte une information précise sur le déplacement en champ lointain par rapport à la position de la faille. Ceci permet d'une part de réduire les incertitudes associées aux mesures de déplacement en surface et aux paramètres du modèle, et d'autre part de détecter les déplacements post-sismiques qui existent potentiellement dans les mesures cosismiques qui couvrent la période de mouvement post-sismique. Par ailleurs, la prise en compte de l'incertitude épistémique et la proposition de l'approche floue pour gérer ce type d'incertitude, fournissent une vision différente de l'incertitude de mesure connue par la plupart des géophysiciens et complétent la connaissance de l'incertitude aléatoire et l'application de la théorie des probabilités dans ce domaine. En particulier, la gestion de l'incertitude par la théorie des possibilités permet de contourner le problème de sous-estimation d'incertitude par la théorie des probabilités. Enfin, la comparaison du déplacement mesuré par les images SAR avec le déplacement mesuré par les images optiques et le déplacement issu des mesures sur le terrain révèle toute la difficulté d'interpréter différentes sources de données plus ou moins compatibles entre elles. Les outils développés dans le cadre de cette thèse sont intégrés dans le package MDIFF (Methods of Displacement Information Fuzzy Fusion) dans l'ensemble des "EFIDIR Tools" distribués sous licence GPL. / Following the successive launches of satellites for Earth observation with SAR (Synthetic Aperture Radar) sensor, the volume of available radar data is increasing considerably. In this context, fusion of displacement measurements from SAR imagery is promising both in the community of remote sensing and in geophysics. With this in mind, this Ph.D thesis proposes to extend conventional approaches by combining SAR image processing techniques, information fusion methods and the knowledge on geophysics. First, this Ph.D thesis aims to explore several fusion strategies, joint inversion, pre-fusion and post-fusion, to reduce the uncertainty associated on the one hand to the estimation of the 3-dimensional (3D) displacement at the Earth's surface, on the other hand to physical modeling that describes the source in depth of the displacement observed at the Earth's surface. We evaluate advantages and disadvantages of each fusion strategy in terms of reducing uncertainty and of robustness against noise. Second, we aim to take account of epistemic uncertainty, in addition to the random uncertainty present in the measurements and propose the conventional and fuzzy approaches based on probability theory and possibility theory respectively to model these uncertainties. We analyze and highlight the efficiency of each approach in context of each fusion strategy. The first application consists of estimating the 3D displacement fields at the Earth's surface due to the Kashmir earthquake in October 2005 and the eruption of Piton de la Fournaise in January 2004 on Reunion Island. The second application involves the modeling of the fault rupture in depth related to the Kashmir earthquake. The main achievements and contributions are evaluated from a methodological point of view in information processing and from a geophysical point of view. In the methodological view, in order to address the major difficulties encountered in the application of differential interferometry for measuring the displacement induced by the Kashmir earthquake, a multi-scale strategy based on prior information issued from a deformation model using local frequencies of interferometric phase is adopted successfully. Regarding the measurement uncertainty management, both random and epistemic uncertainties are analyzed and identified in the displacement measurements. The conventional approach and a fuzzy approach based on respectively probability theory and possibility theory are proposed to model uncertainties and manage the uncertainty propagation in the fusion system. In addition, comparisons between possibility distributions enrich the comparisons made simply between displacement values and indicate the relevance of possibility distributions in the considered context. Furthermore, pre-fusion and post-fusion, two fusion strategies different from the commonly used fusion strategy of joint inversion, are proposed to reduce heterogeous uncertainties present in practice in the measurements and to get around the main limitations of joint inversion. Appropriated conditions of the application of each uncertainty management approach are highlighted in the context of these fusion strategies. In the geophysical view, the application of differential interferometry to the Kashmir earthquake is performed successfully for the first time and it completes previous studies based on measurements from the correlation of SAR and optical images, teleseismic measurements and in situ field measurements. Differential interferometry provides accurate displacement information in the far field relative to the fault position. This allows on the one hand reducing uncertainties associated with surface displacement measurements and with model parameters, on the other hand detecting post-seismic movements that exist potentially in the used coseismic measurements covering the post-seismic period. Moreover, taking into consideration of epistemic uncertainty and the proposition of a fuzzy approach for its management, provide a different view of the measurement uncertainty known by most geophysicists and complete the knowledge of the random uncertainty and the application of probability theory in this domain. In particular, the management of uncertainty by possibility theory allows overcoming the problem of under-estimation of uncertainty by probability theory. Finally, comparisons of the displacement measured by SAR images with the displacement measured by optical images and the displacement from in situ field measurements reveal the difficulty to interpret different data sources more or less compatible among them. The tools developed during this Ph.D thesis are included in the MDIFF (Methods of Displacement Information Fuzzy Fusion) package in "EFIDIR Tools" distributed under the GPL lisence.
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Contribuição ao desenvolvimento de transdutores indutivos de deslocamentoMotta, Eduardo Costa da January 2002 (has links)
O presente trabalho enfoca o estudo de transdutores indutivos de deslocamento linear. Dentre os diversos dispositivos dessa natureza, procurou-se desenvolver um estudo mais aprofundado do transdutor indutivo diferencial com núcleo de esferas. O desenvolvimento experimental, com a construção de quatro protótipos, levou ao projeto de um transdutor com características adequadas ao uso industrial. / The present work focuses on the study of inductive transducers of linear displacement. Among the several devices of that nature, a more detailed study of the inductive differential transducer was attempted with core of spherical balls. The experimental development of four prototypes resulted in a transducer with characteristics adequate for industrial use to be designed.
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Contribuição ao desenvolvimento de transdutores indutivos de deslocamentoMotta, Eduardo Costa da January 2002 (has links)
O presente trabalho enfoca o estudo de transdutores indutivos de deslocamento linear. Dentre os diversos dispositivos dessa natureza, procurou-se desenvolver um estudo mais aprofundado do transdutor indutivo diferencial com núcleo de esferas. O desenvolvimento experimental, com a construção de quatro protótipos, levou ao projeto de um transdutor com características adequadas ao uso industrial. / The present work focuses on the study of inductive transducers of linear displacement. Among the several devices of that nature, a more detailed study of the inductive differential transducer was attempted with core of spherical balls. The experimental development of four prototypes resulted in a transducer with characteristics adequate for industrial use to be designed.
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Fast searching measurement of absolute displacement based on submicron-aperture fiber point-diffraction interferometerWang, Daodang, Wang, Zhichao, Liang, Rongguang, Kong, Ming, Zhao, Jun, Zhao, Jufeng, Mo, Linhai, Li, Wei 26 June 2017 (has links)
The submicron-aperture fiber point-diffraction interferometer (SFPDI) can be applied to realize the measurement of three-dimensional absolute displacement within large range, in which the performance of point-diffraction wavefront and numerical iterative algorithm for displacement reconstruction determines the achievable measurement accuracy, reliability and efficiency of the system. A method based on fast searching particle swarm optimization (FS-PSO) algorithm is proposed to realize the rapid measurement of three-dimensional absolute displacement. Based on the SFPDI with two submicron-aperture fiber pairs, FS-PSO method and the corresponding model of the SFPDI, the measurement accuracy, reliability and efficiency of the SFPDI system are significantly improved, making it more feasible for practical application. The effect of point-diffraction wavefront error on the measurement is analyzed. The error of point-diffraction wavefront obtained in the experiment is in the order of 1x10(-4). (the wavelength. is 532 nm), and the corresponding displacement measurement error is smaller than 0.03 mu m. Both the numerical simulation and comparison experiments have been carried out to demonstrate the accuracy and feasibility of the proposed SFPDI system, high measurement accuracy in the order of 0.1 mu m, convergence rate (similar to 90.0%) and efficiency have been realized with the proposed method, providing a feasible way to measure three-dimensional absolute displacement in the case of no guide rail.
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Fibre-Optic Displacement and Temperature Sensing Using Coupling Based Intensity Modulation and Polarisation Modulation TechniquesJason, Johan January 2013 (has links)
Optical fibre sensors are employed in the measurements of a number of different physical properties or for event detection in safety and security systems. In those environments which suffer from electromagnetic disturbance, in harsh environments where electronics cannot survive and in applications in favour of distributed detection, fibre-optic sensors have found natural areas of use. In some cases they have replaced conventional electronic sensors due to better performance and long-term reliability, but in others they have had less success mainly due to the higher costs which are often involved in fibre-optic sensor systems. Intensity modulated fibre-optic sensors normally require only low-cost monitoring systems principally based on light emitting diodes and photodiodes. The sensor principle itself is very elemental when based on coupling between fibres, and coupling based intensity modulated sensors have been utilised over a long period of time, mainly within displacement and vibration sensing. For distributed sensing based on intensity modulation, optical time domain reflectometer (OTDR) systems with customised sensor cables have been used in the detection of heat, water leakage and hydrocarbon fluid spills. In this thesis, new concepts for intensity modulated fibre-optic sensors based on coupling between fibres are presented, analysed, simulated and experimentally verified. From a low-cost and standard component perspective, alternative designs are proposed and analysed using modulation function simulations and measurements, in order to find an improved performance. Further, the development and installation of a temperature sensor system for industrial process monitoring is presented, involving aspects with regards to design, calibration, multiplexing and fibre network installation. The OTDR is applied as an efficient technique for multiplexing several coupling based sensors, and sensor network installation with blown fibre in microducts is proposed as a flexible and cost-efficient alternative to traditional cabling. As a solution to alignment issues in coupling based sensors, a new displacement sensor configuration based on a fibre to a multicore fibre coupling and an image sensor readout system is proposed. With this concept a high-performance sensor setup with relaxed alignment demands and a large measurement range is realised. The sensor system performance is analysed theoretically with complete system simulations, and an experimental setup is made based on standard fibre and image acquisition components. Simulations of possible error contributions show that the experimental performance limitation is mainly related to differences between the modelled and the real coupled power distribution. An improved power model is suggested and evaluated experimentally, showing that the experimental performance can be improved down towards the theoretical limit of 1 μm. The potential of using filled side-hole fibres and polarisation analysis for point and distributed detection of temperature limits is investigated as a complement to existing fibre-optic heat detection systems. The behaviour and change in birefringence at the liquid/solid phase transition temperature for the filler substance is shown and experimentally determined for side-hole fibres filled with water solutions and a metal alloy, and the results are supported by simulations. A point sensor for on/off temperature detection based on this principle is suggested. Further the principles of distributed detection by measurements of the change in beat length are demonstrated using polarisation OTDR (POTDR) techniques. It is shown that high-resolution techniques are required for the fibres studied, and side-hole fibres designed with lower birefringence are suggested for future studies in relation to the distributed application. / Fiberoptiska sensorer används för mätning av ett antal olika fysikaliska parametrar eller för händelsedetektering i larm- och säkerhetssystem. I miljöer med elektromagnetiska störningar, i andra besvärliga miljöer där elektronik inte fungerar samt i tillämpningar där distribuerade sensorer är att föredra, har fiberoptiska lösningar funnit naturliga applikationer. I vissa fall har de ersatt konventionella elektroniska sensorer på grund av bättre prestanda och tillförlitlighet, medan de i andra sammanhang har haft mindre framgång huvudsakligen på grund av den i många fall högre kostnaden för fiberoptiska sensorsystem. Intensitetsmodulerade fiberoptiska sensorer kräver normalt endast billiga utläsningssystem huvudsakligen baserade på lysdioder och fotodioder. Principen för sådana sensorer baserade på koppling mellan fibrer är mycket enkel, och denna typ av sensorer har haft tillämpningar under en lång tid, främst inom mätning av positionsförändring och vibrationer. För distribuerade intensitetsmodulerade sensorer har system baserade på optisk tidsdomän-reflektometer (OTDR) och skräddarsydda sensorkablar funnit tillämpningar i detektion av värme/brand, vattenläckage och kolvätebaserade vätskor. I denna avhandling presenteras, simuleras, testas och utvärderas praktiskt några nya koncept för kopplingsbaserade intensitetsmodulerade fiberoptiska sensorer. Från ett lågkostnads- och standardkomponentperspektiv föreslås och analyseras alternativa lösningar för förbättrad prestanda. Utveckling och installation av en temperatursensor för en industriell tillämpning, innehållande aspekter på sensormultiplexering och nätverksbyggande, behandlas. OTDR-teknik används som en effektiv metod för multiplexering av flera kopplingsbaserade sensorer, och installation av sensornätverk genom användning av blåsfiberteknik och mikrodukter föreslås som ett flexibelt och kostnadseffektivt alternativ till traditionell kabelinstallation. Som en lösning på förekommande upplinjeringsproblem för kopplingsbaserade sensorer, föreslås en ny sensorkonfiguration baserad på koppling mellan en fiber och en multikärnefiber/fiberarray och med ett bildsensorsystem för detektering. Med detta koncept kan ett högpresterande, upplinjeringsfritt sensorsystem med ett stort mätområde åstadkommas. Sensorsystemets prestanda har analyserats teoretiskt med kompletta systemsimuleringar, och en experimentell uppställning baserad på standardfiber och en kamera av standardtyp har gjorts. Simuleringar av möjliga felbidrag visar att systemets experimentella prestanda främst begränsas av skillnader mellan den modellerade och den verkliga optiska effektfördelningen. En förbättrad modell för effektfördelningen föreslås och utvärderas experimentellt. Det visas att prestanda är möjlig att förbättra ner mot den teoretiska gräns på 1 μm som erhållits vid systemsimuleringar. Möjligheterna att använda fyllda hålfibrer och polarisationskänslig mätning för detektering av temperaturgränser studeras i syfte att komplettera befintliga fiberoptiska värmedetektorsystem. Förändringen i fiberns dubbelbrytning vid övergångstemperaturen mellan vätske- och fast fas för ämnet i hålen visas och bestäms experimentellt för hålfibrer fyllda med vattenlösningar respektive en metallegering, och resultaten understöds också av simuleringar. En punktsensor för temperaturdetektering baserad på denna princip föreslås. Vidare visas principerna för distribuerad detektering genom registrering av förändringen i dubbelbrytning med polarisations-OTDR (POTDR). Det visas att OTDR-teknik med hög spatial upplösning behövs för övervakning av de studerade fibrerna, och hålfibrer utformade med lägre dubbelbrytning föreslås för framtida studier av tillämpningen.
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Análise teórica de uma nova técnica de processamento de sinais interferométricos baseada na modulação triangular da fase óptica /Takiy, Aline Emy. January 2010 (has links)
Orientador: Cláudio Kitano / Banca: Ricardo Tokio Higuti / Banca: Luiz Antonio Perezi Marçal / Resumo: Neste trabalho estuda-se a interferometria laser, a qual constitui uma técnica adequada para determinar grandezas físicas com sensibilidade extremamente elevada. Basicamente, no interferômetro óptico, a informação a respeito do dispositivo sob teste é inserida na fase da luz. Utilizando-se o fotodiodo, promove-se a transferência de informação, do domínio óptico para o elétrico, no qual pode ser demodulada usando-se as várias técnicas disponíveis na literatura para detectar sinais modulados em fase. Ênfase é dada a um novo método de demodulação de fase óptica auto-consistente e de grande sensibilidade. Neste método, utiliza- se a modulação dada por uma forma de onda triangular e é baseado na análise do espectro do sinal fotodetectado, sendo capaz de estender a faixa dinâmica de demodulação a valores tão elevados quanto às dos métodos clássicos. Simulações dinâmicas computacionais de interferômetros ópticos são executadas em Simulink juntamente com este método, levando-se em consideração tensões de ruído eletrônico do tipo ruído branco, evidenciando a eficiência do método quando comparados com dados teóricos obtidos em Matlab. A validação experimental do método é realizada com o auxílio de um modulador eletro-óptico de amplitudes, cujas características de fase podem ser previstas analiticamente. Trata-se de um sensor polarimétrico baseado em cristal de Niobato de Lítio, em que a diferença de fase óptica induzida pela tensão elétrica aplicada pode ser determinada através de análise espectral, tal como o novo método descrito neste trabalho. Um interferômetro de Michelson homódino de baixo custo é implementado e a eficiência do novo método de demodulação de fase óptica é avaliada através de testes com atuadores e manipuladores piezoelétricos flextensionais, cujas características de linearidade são conhecidas... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: In this work, has been done a study the laser interferometer, which is a technique for determining physical quantities with extremely high sensitivity. Basically, in the optical interferometer, information about the device under test modulates the phase of light. Using a photodiode, promotes the transfer of information from the optical domain for the electric, which can be demodulated using the various techniques available in literature to detect modulated signals in phase. Emphasis is given to a new method of phase demodulation of optical self-consistent and high sensitivity. The method employs a linear modulation given by a triangular waveform, and is based on analysis of the spectrum of the photodetected signal, being able to extend the dynamic range of the demodulation values as high as the classical methods. Dynamic computational simulations of optical interferometers are implemented in Simulink with this method, taking into account strains of electronic noise like white noise, indicating the efficiency of the method compared with theoretical data obtained in Matlab workspace. The experimental validation of the method is performed with the aid of an electro- optic amplitude modulator, whose phase characteristics can be analytically predicted. This is a polarimetric sensor based on lithium niobate crystal, in which the optical phase difference induced by electric voltage can be determined by spectral analysis, using new method described in this work. A low cost homodyne Michelson interferometer is implemented and the efficiency of the new method of optical phase demodulation is evaluated by testing with piezoelectric flextensional actuators whose characteristics of linearity are well known.The experimental results agree with theoretical analysis and reveal this method is more efficient than the classical methods / Mestre
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