Etude théorique et expérimentale de l'holographie intracavité

Menez, Ludivine

01 October 2001

L'utilisation des techniques holographiques pour le traitement optique de l'information est souvent limitée par les performances insuffisantes des dispositifs existants (efficacité de diffraction trop faible, sélectivité restreinte, ou forte diaphonie). L'holographie intracavité peut améliorer ces propriétés de façon considérable.<br />Ce travail a pour objectif l'étude théorique et expérimentale des propriétés diffractives d'un réseau d'indice inséré dans un résonateur de Fabry-Perot, appelé réseau d'indice intracavité. Cette approche fondamentale d'un nouveau concept a conduit à l'élaboration d'un modèle analytique. La diffraction sur un réseau d'indice intracavité épais est ainsi décrite et comparée à celle sur un réseau de Bragg hors cavité. Nous étudions en particulier la diffraction d'une onde de lecture en résonance simultanée avec la cavité de Fabry-Perot et avec le réseau de Bragg. La supériorité du dispositif intracavité en termes d'efficacité de diffraction, de sélectivité angulaire et de rapport signal sur bruit est démontrée. Il apparaît que la configuration la plus favorable est celle d'un résonateur asymétrique, dont le miroir arrière est parfaitement réfléchissant.<br />Compte tenu des résultats théoriques prometteurs, un dispositif expérimental a été conçu, afin de prouver la faisabilité du concept et de valider le modèle analytique. Le milieu non-linéaire support du réseau est un liquide, de sorte que son épaisseur peut être ajustée pour faire coïncider les résonances de Bragg et de Fabry-Perot. Le réseau est inscrit optiquement, par absorption de la figure d'interférence de deux impulsions d'écriture et diffracte le faisceau de lecture continu au voisinage de la résonance de Bragg. Le signal diffracté est analysé pour remonter aux propriétés du réseau. La comparaison avec le réseau de Bragg hors cavité montre l'amélioration significative apportée par le résonateur. Ces résultats expérimentaux sont en très bon accord avec les calculs numériques issus du modèle analytique.<br />Enfin, nous revenons sur le critère de distinction entre réseaux minces (en régime de Raman-Nath) et réseaux épais (régime de Bragg) dans le cas de réseaux intracavité. Nous établissons que le seuil en épaisseur au delà duquel un réseau est épais est nettement abaissé lorsqu'on l'insère en cavité de Fabry-Perot. Le domaine d'application du modèle que nous avons établi est donc très vaste.

[PHYS:PHYS] Physics/Physics

Holographie

Cavité de Fabry-Perot

Diffraction

Réseaux d'indices

Réseau de Bragg

Per mill level control of the Fabry-Perot cavity optical system for precision Compton polarimetry

Jacquet, M.

10 July 2009

Pas de résumé

Fabry-Perot cavity

Compton polarimetry

PRESSURE MEASUREMENT INSTRUMENTATION IN A HIGH TEMPERATURE MOLTEN SALT TEST LOOP

Ritchie, John Andrew

01 December 2010

A high temperature molten salt test loop that utilizes FLiNaK (LiF-NaF-KF) at 700ºC has been proposed by Oak Ridge National Laboratory (ORNL) to study molten salt flow characteristics through a pebble bed for applications in high temperature thermal systems, in particular the Pebble Bed – Advanced High Temperature Reactor (PB-AHTR). The University of Tennessee Nuclear Engineering Department has been tasked with developing and testing pressure instrumentation for direct measurements inside the high temperature environment. A nickel diaphragm based direct contact pressure sensor is developed for use in the salt. Capacitive and interferometric methods are used to infer the displacement of the diaphragm. Two sets of performance data were collected at high temperatures. The fiber optic, Fabry-Perot interferometric sensor was tested in a molten salt bath. The capacitive pressure sensor was tested at high temperatures in a furnace under argon cover gas.

Molten Salt

Pebble Bed

High Temperature Reactor

Diaphragm

Pressure Sensor

Fabry Perot

Nuclear Engineering

Design and fabrication of highly efficient electrooptic modulators using bragg grating reflectors

Kim, Ryoung-Han

12 April 2006

Bragg grating reflectors etched in amorphous silicon overlay films have been integrated with Ti:LiNbO3 optical waveguides. With a 12.5 mm long grating segment and an etch depth of ~ 93 nm in a 105 nm-thick silicon film, a narrow (0.05 nm) spectral bandwidth with a record high transmission dip (> 20 dB) was achieved at a wavelength of ~1542 nm for TE polarization on an x-cut, y-propagating substrate. The reflectance in the channel waveguides is found to be strongly dependent on the depth of the etched grating. The 3-dB bandwidth of 0.05 nm obtained for all tested samples is the smallest reported for waveguides in LiNbO3. The effect of the Bragg waveguide loss factor on the transmittance and reflectance spectra is investigated using a model for contra-directional coupling that includes an attenuation coefficient. The Bragg grating spectral characteristics are exploited to fabricate distributed Bragg feedback modulators (DBFM) and Bragg reflector Fabry-Perot modulators (BFPM). The sharp cut-off in transmission and reflection spectra, which is an inherent characteristic of Bragg grating, was tuned by applying voltage via the linear electrooptic effect, to produce intensity modulation. The Bragg grating based modulators consume less electric power compared to polarization intensity modulators (PIMs). The DBFM demonstrates 1/1.6 times the modulating voltage of a PIM with identical waveguide and electrode structure. The BFPM shows 1/3.3 times the modulating voltage of the PIM. No difference in the frequency response is observed among the three modulators. Comparison of the modulation sensitivity in the linear region indicates that the Bragg grating based modulators provide better sensitivity than that of the PIM with identical waveguide and electrode structure. These results indicate the potential advantage of the Bragg grating based modulators for enhanced modulation efficiency over conventional modulators. Further improvements can be expected from the optimization of the electrode design.

electro-optic

modulator

Bragg grating

fabry-Perot

intensity modulation

lithium niobate

Fiber Fabry-Perot interferometer (FFPI) sensor using vertical cavity surface emitting laser (VCSEL)

Lee, Kyung-Woo

30 October 2006

This research represents the first effort to apply vertical cavity surface emitting lasers (VCSELs) to the monitoring of interferometric fiber optic sensors. Modulation of the drive current causes thermal tuning of the laser light frequency. Reflection of this frequency-modulated light from a fiber Fabry-Perot interferometer (FFPI) sensor produces fringe patterns which can be used to measure the optical path difference of the sensor. Spectral characteristics were measured for 850nm VCSELs to determine the combination of dc bias current, modulation current amplitude and modulation frequency for which single mode VCSEL operation and regular fringe patterns are achieved. The response characteristics of FFPI sensors were determined experimentally for square, triangular, saw-tooth waveforms at frequencies from 10kHz to 100kHz. The dependence of VCSEL frequency on the dc bias current was determined from spectral measurements to be ~165GHz/mA. An independent measurement of this quantity based on counting fringes from the FFPI sensor as the laser modulated was in good agreement with this value. The effect of optical feedback into the laser was also studied. By observing the fringe shift as the FFPI sensor was heated, a fractional change in optical length with temperature of 6.95 X 10-6/°C was determined in good agreement with previous measurements on a 1300nm single mode fiber. The performance of 850nm VCSEL/FFPI systems was compared with their counterparts using 1300nm distributed feedback (DFB) lasers. The results of these experiments show that the 850nm VCSEL/FFPI combination gives regular fringe patterns at much lower bias current and modulating current amplitudes than their 1300nm DFB/FFPI counterparts.

fiber

fabry-perot

interferometer

sensor

ffpi

vcsel

vertical

cavity

surface

emitting

laser

Design and fabrication of highly efficient electrooptic modulators using bragg grating reflectors

Kim, Ryoung-Han

12 April 2006

Bragg grating reflectors etched in amorphous silicon overlay films have been integrated with Ti:LiNbO3 optical waveguides. With a 12.5 mm long grating segment and an etch depth of ~ 93 nm in a 105 nm-thick silicon film, a narrow (0.05 nm) spectral bandwidth with a record high transmission dip (> 20 dB) was achieved at a wavelength of ~1542 nm for TE polarization on an x-cut, y-propagating substrate. The reflectance in the channel waveguides is found to be strongly dependent on the depth of the etched grating. The 3-dB bandwidth of 0.05 nm obtained for all tested samples is the smallest reported for waveguides in LiNbO3. The effect of the Bragg waveguide loss factor on the transmittance and reflectance spectra is investigated using a model for contra-directional coupling that includes an attenuation coefficient. The Bragg grating spectral characteristics are exploited to fabricate distributed Bragg feedback modulators (DBFM) and Bragg reflector Fabry-Perot modulators (BFPM). The sharp cut-off in transmission and reflection spectra, which is an inherent characteristic of Bragg grating, was tuned by applying voltage via the linear electrooptic effect, to produce intensity modulation. The Bragg grating based modulators consume less electric power compared to polarization intensity modulators (PIMs). The DBFM demonstrates 1/1.6 times the modulating voltage of a PIM with identical waveguide and electrode structure. The BFPM shows 1/3.3 times the modulating voltage of the PIM. No difference in the frequency response is observed among the three modulators. Comparison of the modulation sensitivity in the linear region indicates that the Bragg grating based modulators provide better sensitivity than that of the PIM with identical waveguide and electrode structure. These results indicate the potential advantage of the Bragg grating based modulators for enhanced modulation efficiency over conventional modulators. Further improvements can be expected from the optimization of the electrode design.

electro-optic

modulator

Bragg grating

fabry-Perot

intensity modulation

lithium niobate

Fiber Fabry-Perot interferometer (FFPI) sensor using vertical cavity surface emitting laser (VCSEL)

Lee, Kyung-Woo

30 October 2006

This research represents the first effort to apply vertical cavity surface emitting lasers (VCSELs) to the monitoring of interferometric fiber optic sensors. Modulation of the drive current causes thermal tuning of the laser light frequency. Reflection of this frequency-modulated light from a fiber Fabry-Perot interferometer (FFPI) sensor produces fringe patterns which can be used to measure the optical path difference of the sensor. Spectral characteristics were measured for 850nm VCSELs to determine the combination of dc bias current, modulation current amplitude and modulation frequency for which single mode VCSEL operation and regular fringe patterns are achieved. The response characteristics of FFPI sensors were determined experimentally for square, triangular, saw-tooth waveforms at frequencies from 10kHz to 100kHz. The dependence of VCSEL frequency on the dc bias current was determined from spectral measurements to be ~165GHz/mA. An independent measurement of this quantity based on counting fringes from the FFPI sensor as the laser modulated was in good agreement with this value. The effect of optical feedback into the laser was also studied. By observing the fringe shift as the FFPI sensor was heated, a fractional change in optical length with temperature of 6.95 X 10-6/°C was determined in good agreement with previous measurements on a 1300nm single mode fiber. The performance of 850nm VCSEL/FFPI systems was compared with their counterparts using 1300nm distributed feedback (DFB) lasers. The results of these experiments show that the 850nm VCSEL/FFPI combination gives regular fringe patterns at much lower bias current and modulating current amplitudes than their 1300nm DFB/FFPI counterparts.

fiber

fabry-perot

interferometer

sensor

ffpi

vcsel

vertical

cavity

surface

emitting

laser

Investigation into High Spectral Resolution Lidar Technologies

Dawsey, Martha Wallis

January 2013

The Intergovernmental Panel on Climate Change (IPCC) found in their 2007 report that aerosol radiative forcing contributed larger uncertainties to estimates affecting future climate change than any other radiative forcing factor. Lidar is a tool with which this uncertainty can be reduced, increasing our understanding of the impact of aerosols on climate change. Lidar, or laser radar, is a monostatic active remote sensing technique used to measure aerosols and particulates in the atmosphere, with accuracies comparable to in-situ measurements (Russell 2002). High Spectral Resolution Lidar (HSRL) systems use a narrow band filter to spectrally separate Doppler broadened aerosol and molecular back-scattered return signals, which allows for range resolved profiles of aerosol extinction and backscatter. The narrow band filter is a key component, for which two novel approaches are currently being used: NASA Langley Research Center has implemented a wide-angle Michelson interferometer in the second version of their airborne HSRL, and Montana State University is using a spherical Fabry-Perot interferometer in a ground based HSRL. In this research, a comprehensive comparative analysis of these two interferometric filters is performed, the result of which is a methodology for the design of narrow band filters for HSRL systems. The techniques presented identify the critical components and analyze the performance of each filter based on the spectral and angular properties, as well as the efficiency.

Fabry-Perot

filter

high spectral resolution lidar

lidar

Michelson

Optical Sciences

design

SLOW-LIGHT PHYSICS FOR ALL-OPTICAL TUNABLE DELAY

Pant, Ravi

January 2009

High-speed optical networks will require all-optical signalprocessing to avoid bottleneck due to optical-to-electrical (O/E)and electrical-to-optical (E/O) conversion. Enabling of opticalprocessing tasks such as optical buffering and data synchronizationwill require large tunable delay. Recently, slow-light physics gotwide attention to generate tunable delay. However, for a slow-lightsystem large delay comes at the expense of increased distortion.This dissertation presents a study of the slow-light systems andquantifies the limitations imposed on delay due to distortion andsystem resource constraints. Optimal designs for two- and three-lineBrillouin slow-light systems showed fractional pulse delay of up to1.7 compared to a single-line gain system. Optimal designs forbroadband Brillouin gain system showed upto 100\% delay improvementcompared to the Gaussian pump. Wavelength conversion and dispersionbased tunable delay systems showed bit delay of 15 bits. An opticalbuffer based on photorefractive medium for real-time data storagewas demonstrated by storing and retrieving a 7-bit data sequence.

Fabry-perot

Bragg grating

Photorefractive optical buffer

slow light

Stimulated Brillouin Scattering

Wavelength conversion

Cinématique haute résolution des galaxies de l'échantillon SINGS et observations du H[alpha] profond de la galaxie NGC 7793

Dicaire, Isabelle

January 2007

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal

Méthodes : observationnelles

Technique : vitesses radiales