Estudo de materiais fotorrefrativos e suas aplicações no processamento óptico holográfico de informação / Study of photorefractive materials and their applications in holographic optical processing of information

Gesualdi, Marcos Roberto da Rocha

31 January 2005

O Estudo de Materiais Fotorrefrativos e suas Aplicações no Processamento Óptico Holográfico de Informação vêm sendo feitos por diversos Grupos de Pesquisas em vários laboratórios devido aos bons resultados obtidos com esses meios em diversas áreas. Entre outros efeitos foto-induzidos o processo que possibilita essas aplicações é o efeito fotorrefrativo, um fenômeno onde o registro holográfico no meio fotorrefrativo ocorre pela modulação do índice de refração de acordo com a distribuição espacial da intensidade da luz incidente, devido a uma redistribuição foto-induzida de cargas espaciais, e conseqüente, geração de um campo espaço-carga no meio. Neste trabalho, estuda-se a propagação e acoplamento de ondas eletromagnéticas em monocristais elétro-ópticos paraelétricos da Família das Silenitas \'BI IND. 12\'\'SI\'\'O IND. 20\' (BSO) e \'BI IND. 12\'\'TI\'\'O IND. 20\' (BTO) e nos ferroelétricos \'LI\'\'NB\'\'O IND. 3\' puros e dopados. O propósito de estudar esses materiais é caracterizá-los e, principalmente, otimizá-los para aplicação no processamento óptico e holográfico de informação. Utiliza-se técnicas de caracterização de redes holográficas fotorrefrativas e de lentes foto-induzidas para determinação de figuras de mérito e parâmetros fotorrefrativos e termo-ópticos nestes meios fotorrefrativos. Propõe-se também algumas aplicações no processamento óptico e holográfico de informação, nas áreas de pesquisa básica, tecnológicas e biomédicas, que vêm despertando grande interesse nos últimos anos, como holografia em tempo real com mapeamento de fase, interterometria speckle em tempo real e registro não-holográfico no processo de conversão incoerente-incoerente; entre outras no processamento óptico e holográfico de dados. / The Study of Photorefractive Materials and their Applications in Optical and Holographical Information Processing come being made for diverse Groups of Research in some laboratories due to the good results in many areas. Among other photo-induced effects, the process that allows these applications is the photorefractive effect, a phenomenon where the holographic recording in photorefractive medium occurs by means of the refractive index modulation due to the space distribution of the light intensity, producing a space-charge photo-induced redistribution, and consequently, the generation of a space-charge field governed by an electro-optic medium. In this work, we study the propagation and coupling of electromagnetic waves in electro-optic monocrystals of the sillemite family Bi12SiO20 (BSO) and Bi12TiO20 (BTO) and in the pure and dop-ed LiNbO3 crystals. The purpose to study these materials is to characterize them and, mainly, to optimize the conditions of their application in the optical and holographical information processing. We use photorefractive holographic gratings and photo-induced lens techniques for determination of figures of merit and photorefractive and thermo-optic parameters in these photorefractive materials. We also consider some applications in the optical and holographical information processing in the research basic, technological and biomedical areas, that come waken great interest in the last years, as phase- shifting real-time holography, real-time speckle interferometry and non-holographic recording with incoherent-incoherent conversion process; among others in the optic and holographic data processing.

Física óptica

Holografia

Holography

Interference of light

Interferência da luz

Optical signal processing

Physical optics

Processamento de sinais ópticos

All-Optical Clock Recovery, Photonic Balancing, and Saturated Asymmetric Filtering For Fiber Optic Communication Systems

Parsons, Earl Ryan

January 2010

In this dissertation I investigated a multi-channel and multi-bit rate all-optical clock recovery device. This device, a birefringent Fabry-Perot resonator, had previously been demonstrated to simultaneously recover the clock signal from 10 wavelength channels operating at 10 Gb/s and one channel at 40 Gb/s. Similar to clock signals recovered from a conventional Fabry-Perot resonator, the clock signal from the birefringent resonator suffers from a bit pattern effect. I investigated this bit pattern effect for birefringent resonators numerically and experimentally and found that the bit pattern effect is less prominent than for clock signals from a conventional Fabry-Perot resonator.I also demonstrated photonic balancing which is an all-optical alternative to electrical balanced detection for phase shift keyed signals. An RZ-DPSK data signal was demodulated using a delay interferometer. The two logically opposite outputs from the delay interferometer then counter-propagated in a saturated SOA. This process created a differential signal which used all the signal power present in two consecutive symbols. I showed that this scheme could provide an optical alternative to electrical balanced detection by reducing the required OSNR by 3 dB.I also show how this method can provide amplitude regeneration to a signal after modulation format conversion. In this case an RZ-DPSK signal was converted to an amplitude modulation signal by the delay interferometer. The resulting amplitude modulated signal is degraded by both the amplitude noise and the phase noise of the original signal. The two logically opposite outputs from the delay interferometer again counter-propagated in a saturated SOA. Through limiting amplification and noise modulation this scheme provided amplitude regeneration and improved the Q-factor of the demodulated signal by 3.5 dB.Finally I investigated how SPM provided by the SOA can provide a method to reduce the in-band noise of a communication signal. The marks, which represented data, experienced a spectral shift due to SPM while the spaces, which consisted of noise, did not. A bandpass filter placed after the SOA then selected the signal and filtered out what was originally in-band noise. The receiver sensitivity was improved by 3 dB.

All-Optical Regeneration

All-Optical Signal Processing

Balanced Detection

Clock Recovery

In-Band Noise Filtering

Estudo de materiais fotorrefrativos e suas aplicações no processamento óptico holográfico de informação / Study of photorefractive materials and their applications in holographic optical processing of information

Marcos Roberto da Rocha Gesualdi

31 January 2005

O Estudo de Materiais Fotorrefrativos e suas Aplicações no Processamento Óptico Holográfico de Informação vêm sendo feitos por diversos Grupos de Pesquisas em vários laboratórios devido aos bons resultados obtidos com esses meios em diversas áreas. Entre outros efeitos foto-induzidos o processo que possibilita essas aplicações é o efeito fotorrefrativo, um fenômeno onde o registro holográfico no meio fotorrefrativo ocorre pela modulação do índice de refração de acordo com a distribuição espacial da intensidade da luz incidente, devido a uma redistribuição foto-induzida de cargas espaciais, e conseqüente, geração de um campo espaço-carga no meio. Neste trabalho, estuda-se a propagação e acoplamento de ondas eletromagnéticas em monocristais elétro-ópticos paraelétricos da Família das Silenitas \'BI IND. 12\'\'SI\'\'O IND. 20\' (BSO) e \'BI IND. 12\'\'TI\'\'O IND. 20\' (BTO) e nos ferroelétricos \'LI\'\'NB\'\'O IND. 3\' puros e dopados. O propósito de estudar esses materiais é caracterizá-los e, principalmente, otimizá-los para aplicação no processamento óptico e holográfico de informação. Utiliza-se técnicas de caracterização de redes holográficas fotorrefrativas e de lentes foto-induzidas para determinação de figuras de mérito e parâmetros fotorrefrativos e termo-ópticos nestes meios fotorrefrativos. Propõe-se também algumas aplicações no processamento óptico e holográfico de informação, nas áreas de pesquisa básica, tecnológicas e biomédicas, que vêm despertando grande interesse nos últimos anos, como holografia em tempo real com mapeamento de fase, interterometria speckle em tempo real e registro não-holográfico no processo de conversão incoerente-incoerente; entre outras no processamento óptico e holográfico de dados. / The Study of Photorefractive Materials and their Applications in Optical and Holographical Information Processing come being made for diverse Groups of Research in some laboratories due to the good results in many areas. Among other photo-induced effects, the process that allows these applications is the photorefractive effect, a phenomenon where the holographic recording in photorefractive medium occurs by means of the refractive index modulation due to the space distribution of the light intensity, producing a space-charge photo-induced redistribution, and consequently, the generation of a space-charge field governed by an electro-optic medium. In this work, we study the propagation and coupling of electromagnetic waves in electro-optic monocrystals of the sillemite family Bi12SiO20 (BSO) and Bi12TiO20 (BTO) and in the pure and dop-ed LiNbO3 crystals. The purpose to study these materials is to characterize them and, mainly, to optimize the conditions of their application in the optical and holographical information processing. We use photorefractive holographic gratings and photo-induced lens techniques for determination of figures of merit and photorefractive and thermo-optic parameters in these photorefractive materials. We also consider some applications in the optical and holographical information processing in the research basic, technological and biomedical areas, that come waken great interest in the last years, as phase- shifting real-time holography, real-time speckle interferometry and non-holographic recording with incoherent-incoherent conversion process; among others in the optic and holographic data processing.

Física óptica

Holografia

Interferência da luz

Processamento de sinais ópticos

Holography

Interference of light

Optical signal processing

Physical optics

Multi-Core Fiber and Optical Supersymmetry: Theory and Applications

Macho Ortiz, Andrés

02 September 2019

[ES] A día de hoy, las redes de comunicaciones de fibra óptica están alcanzando su capacidad límite debido al rápido crecimiento de la demanda de datos en la última década, generado por el auge de los teléfonos inteligentes, las tabletas, las redes sociales, la provisión de servicios en la nube, las transmisiones en streaming y las comunicaciones máquina-a-máquina. Con el fin de solventar dicho problema, se ha propuesto incrementar la capacidad límite de las redes ópticas mediante el reemplazo de la fibra óptica clásica por la fibra óptica multinúcleo (MCF, acrónimo en inglés de multi-core fiber), la cual es capaz de integrar la capacidad de varias fibras ópticas clásicas en su estructura ocupando prácticamente la misma sección transversal que éstas. Sin embargo, explotar todo el potencial de una fibra MCF requiere entender en profundidad los fenómenos electromagnéticos que aparecen en este tipo de fibras cuando guiamos luz a travésde ellas. Así pues, en la primera parte de la tesis se analizan teóricamente estos fenómenos electromagnéticos y, posteriormente, se estudia la viabilidad de la tecnología MCF en distintos tipos de redes ópticas de transporte, específicamente, en aquellas que hacen uso de transmisiones radio-sobre-fibra. Estos resultados pueden ser de gran utilidad para las futuras generaciones móviles 5G y Beyond-5G en las próximas décadas. Adicionalmente, con el fin de expandir las funcionalidades básicas de las fibras MCF, esta tesis explora nuevas estrategias de diseño de las mismas utilizando la analogía existente entre las ecuaciones que rigen la mecánica cuántica y el electromagnetismo. Con esta idea en mente, en la segunda parte de la tesis se propone diseñar una nueva clase de fibras MCF usando las matemáticas de la supersimetría, surgida en el seno de la teoría de cuerdas y de la teoría cuántica de campos como un marco teórico de trabajo que permite unificar las interacciones fundamentales de la naturaleza (la nuclear fuerte, la nuclear débil, el electromagnetismo y la gravedad). Girando en torno a esta idea surgen las fibras MCF supersimétricas, las cuales nos permiten procesar la información de los usuarios durante la propia propagación de la luz a través de ellas, reduciendo así la complejidad del procesado de datos del usuario en recepción. Finalmente, esta tesis se completa introduciendo un cambio de paradigma que permite diseñar dispositivos fotónicos disruptivos. Demostramos que la supersimetría de mecánica cuántica no relativista, propuesta como una serie de transformaciones matemáticas restringidas al dominio espacial, se puede extender también al dominio del tiempo, al menos dentro del marco de trabajo de la fotónica. Como resultado de nuestras investigaciones, demostramos que la supersimetría temporal puede convertirse en una plataforma prometedora para la fotónica integrada ya que nos permite diseñar nuevos dispositivos ópticos versátiles y ultra-compactos que pueden jugar un papel clave en los procesadores del futuro. Asimismo, con el fin de hacer los resultados principales de esta tesis doctoral lo más generales posibles, se detalla cómo poder extrapolarlos a otros campos de la física como acústica y mecánica cuántica. / [CAT] Avui en dia, les xarxes de comunicacions de fibra òptica estan aconseguint la seua capacitat límit a causa del ràpid creixement de la demanda de dades duante l'última dècada, generat per l'auge dels telèfons intel·ligents, les tablets, les xarxes socials, la provisió de servicis en la núvol, les transmissions en streaming i les comunicacions màquina-a-màquina. Per a resoldre el dit problema, s'ha proposat incrementar la capacitat límit de les xarxes òptiques per mitjà del reemplaçament de la fibra òptica clàssica per la fibra òptica multinúcleo (MCF, acrònim en anglés de multi-core fiber), la qual és capaç d'integrar la capacitat de diverses fibres òptiques clàssiques en la seua estructura ocupant pràcticament la mateixa secció transversal que estes. Tanmateix, explotar tot el potencial d'una fibra MCF requereix entendre en profunditat els fenòmens electromagnètics que apareixen en aquestes fibres quan guiem llum a través d'elles. Així, doncs, en la primera part de la tesi analitzem teòricament aquests fenòmens electromagnètics i, posteriorment, estudiem la viabilitat de la tecnologia MCF en distints tipus de xarxes òptiques de transport, específicament, en aquelles que fan ús de transmissions ràdio-sobre-fibra. Estos resultats poden ser de gran utilitat per a les futures generacions mòbils 5G i Beyond-5G en les pròximes dècades. Addicionalment, a fi d'expandir les funcionalitats bàsiques de les fibres MCF, esta tesi explora noves estratègies de disseny de les mateixes utilitzant l'analogia existent entre les equacions que regixen la mecànica quàntica i l'electromagnetisme. Amb aquesta idea en ment, en la segona part de la tesi proposem dissenyar una nova classe de fibres MCF usant les matemàtiques de la supersimetria, sorgida en el si de la teoria de cordes i de la teoria quàntica de camps com un marc teòric de treball que permet unificar les interaccions fonamentals de la natura (la nuclear forta, la nuclear feble, l'electromagnetisme i la gravetat). Al voltant d'aquesta idea sorgeixen les fibres MCF supersimètriques, les quals ens permeten processar la informació dels usuaris durant la pròpia propagació de la llum a través d'elles, reduint així la complexitat del processament de dades de l'usuari a recepció. Finalment, esta tesi es completa introduint un canvi de paradigma que permet dissenyar dispositius fotónicos disruptius. Demostrem que la supersimetria de mecànica quàntica no relativista, proposta com una sèrie de transformacions matemàtiques restringides al domini espacial, es pot estendre també al domini del temps, almenys dins del marc de treball de la fotónica. Com resultat de les nostres investigacions, demostrem que la supersimetria temporal pot convertir-se en una plataforma prometedora per a la fotònica integrada ja que ens permet dissenyar nous dispositius òptics versàtils i ultracompactes que poden jugar un paper clau en els processadors del futur. Per tal de fer els resultats principals d'aquesta tesi doctoral el més generals possibles, es detalla com poder extrapolar-los a altres camps de la física com ara la acústica i la mecànica quàntica. / [EN] To date, communication networks based on optical fibers are rapidly approaching their capacity limit as a direct consequence of the increment of the data traffic demand in the last decade due to the ubiquity of smartphones, tablets, social networks, cloud computing applications, streaming services including video and gaming, and machine-to-machine communications. In such a scenario, a new class of optical fiber which is able to integrate the capacity of several classical optical fibers approximately in the same transverse section as that of the original one, the multi-core fiber (MCF), has been recently proposed to overcome the capacity limits of current optical networks. However, the possibility of exploiting the full potential of an MCF requires to deeply understand the electromagnetic phenomena that can be observed when guiding light in this optical medium. In this vein, in the first part of this thesis, we analyze theoretically these phenomena and, next, we study the suitability of the MCF technology in optical transport networks using radio-over-fiber transmissions. These findings could be of great utility for 5G and Beyond-5G cellular technology in the next decades. In addition, the close connection between the mathematical framework of quantum mechanics and electromagnetism becomes a great opportunity to explore ground-breaking design strategies of these new fibers that allow us to expand their basic functionalities. Revolving around this idea, in the second part of this thesis we propose to design a new class of MCFs using the mathematics of supersymmetry (SUSY), emerged within the context of string and quantum field theory as a means to unify the basic interactions of nature (strong, electroweak, and gravitational interactions). Interestingly, a supersymmetric MCF will allow us, not only to propagate the light, but also to process the information of users during propagation. Finally, we conclude this thesis by introducing a paradigm shift that allows us to design disruptive optical devices. We demonstrate that the basic ideas of SUSY in non-relativistic quantum mechanics, restricted to the space domain to clarify unsolved questions about SUSY in string and quantum field theory, can also be extended to the time domain, at least within the framework of photonics. In this way, it is shown that temporal supersymmetry may serve as a key tool to judiciously design versatile and ultra-compact optical devices enabling a promising new platform for integrated photonics. For the sake of completeness, we indicate how to extrapolate the main results of this thesis to other fields of physics, such as acoustics and quantum mechanics. / Macho Ortiz, A. (2019). Multi-Core Fiber and Optical Supersymmetry: Theory and Applications [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/124964 / TESIS

TEORIA DE LA SEÑAL Y COMUNICACIONES

An implementation of TD/CCSK waveform using optical signal processing

Chindapol, Aik

January 1996

No description available.

Cyclic Code Shift Keying

TD/CCSK Rake System

Optical Signal Processing

The spherical fourier cell and application for true-time delay

Rabb, David J.

07 January 2008

No description available.

optical time delay

Fourier optics

optical signal processing

phased array antennas

Reconfigurable silicon photonic devices for optical signal processing

Atabaki, Amir Hossein

07 July 2011

Processing of high-speed data using optical signals is a promising approach for tackling the bandwidth and speed challenges of today's electronics. Realization of complex optical signal processing functionalities seems more possible than any time before, thanks to the recent achievements in silicon photonics towards large-scale photonic integration. In this Ph.D. work, a novel thermal reconfiguration technology is proposed and experimentally demonstrated for silicon photonics that is compact, low-loss, low-power, fast, with a large tuning-range. These properties are all required for large-scale optical signal processing and had not been simultaneously achieved in a single device technology prior to this work. This device technology is applied to a new class of resonator-based devices for reconfigurable nonlinear optical signal processing. For the first time, we have demonstrated the possibility of resonance wavelength tuning of individual resonances and their coupling coefficients. Using this new device concept, we have demonstrated tunable wavelength-conversion through four-wave mixing in a resonator-based silicon device for the first time.

Thermal reconfiguration

Nonlinear optics

Optical signal processing

Silicon photonics

Optical resonators

Fiber optics

Photonics

Optical fibers

Silicones

Geração de sinais ópticos multi-níveis a partir de amplificação paramétrica em fibras ópticas / Optical signals multi-levels generation through parametric amplification in optical fibers

Costa, André Luiz Aguiar da

19 August 2018

Orientadores: Edson Moschim, Marcelo Luís Francisco Abbade / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Elétrica e de Computação / Made available in DSpace on 2018-08-19T01:03:29Z (GMT). No. of bitstreams: 1 Costa_AndreLuizAguiarda_D.pdf: 10372929 bytes, checksum: d9a9fba8345bb6152e472fda3ff293e6 (MD5) Previous issue date: 2011 / Resumo: Neste trabalho foram investigadas através de experimentos e simulações computacionais duas novas técnicas de processamento óptico de sinais, que utilizam amplificação paramétrica para multiplexar as informações de dois sinais binários em um único sinal multi-nível. Na primeira delas, o sinal multi-nível corresponde a um sinal quaternário em amplitude, enquanto na segunda este e um sinal ternário em amplitude. Ao contrario da amplificação paramétrica convencional, que utiliza um sinal de bombeio continuo (cw, continuous wave), em ambas as técnicas analisadas neste trabalho, tanto o sinal de bombeio quanto o sinal de prova são modulados em amplitude por duas sequências independentes de bits (informações). Tais sinais são acoplados e propagados por uma fibra óptica. A interação não-linear entre eles, decorrente do processo de amplificação paramétrica, proporciona a multiplexação das informações dos sinais de bombeio e de prova em uma mesma banda. Para os sinais quaternários, os sinais de bombeio e de prova podem apresentar ou não mesma taxa de transmissão, sendo possível ate dobrar a taxa de transmissão dos sinais originais. Verificou-se que a distribuição de seus níveis de potencia e controlada pelas razoes de extinção do sinal de bombeio e de prova. A máxima diferença obtida entre os resultados analíticos e de simulações em relação aos experimentais foi inferior a 1.4 dB. Os experimentos mostraram também que taxas de erro de bit (BER, Bit Erro Rate) inferiores a 7.6 .10-12 podem ser obtidas mesmo apos o sinal quaternário ser propagado por 75 km. Com relação aos sinais ternários, o sinal de prova deve apresentar uma taxa de transmissão N vezes maior que o sinal de bombeio, sendo N inteiro e maior que dois. A taxa de transmissão deste tipo de sinal multi-nível e a soma das taxas de transmissão dos sinais originais. Verificou-se também que com o ajuste da potencia do sinal de bombeio, e possível obter quaisquer razoes de extinção entre o terceiro e o segundo níveis, tornando possível adequar o sinal ternário para minimizar a BER independente do regime de ruído dominante. Apos a propagação do sinal ternário, por 40 km de uma rede de teste de campo, os melhores valores encontrados de BER foram inferiores a 3.5 10-15. Estes baixos valores de BER indicam que ambas as técnicas analisadas podem ser aplicadas a situações práticas / Abstract: In this work two new all-optical signal processing techniques are investigated through computer simulations and experiments; they utilize parametric amplification to multiplex information of two binary input signals into a single multi-level one. In the first of these techniques the multilevel signal corresponds to a quaternary-amplitude one, whereas in the other technique it is a ternary-amplitude signal. In opposition to conventional parametric amplification, where the pump is a continuous wave signal that interacts with one or more modulated probe signals, in both techniques analyzed in this work, the pump and probe signals are modulated by two independent bit sequences. Such signals are coupled and propagated through an optical fiber where parametric interaction causes information carried by these signals to be multiplexed in a single bandwidth. In the generation of quaternary-amplitude signals (QAS), the bit rates of the pump and probe signals may but do not need to be the same; thus, the QAS may convey twice information as each individual binary input signal. It is theoretically demonstrated and experimentally verified that the power level distribution of the QAS may be properly regulated by changing the extinction ratios of the pump and probe signals. Results concerning this analysis show that predictions based on the analytical model presented in this thesis and simulation results are at most 1.4 dB apart from experimental measurements; this is a quite good agreement. Experiments showed that bit error rates (BERs) as low as 7.6 .10-12 may be obtained even after the QAS is propagated for 75 km of standard fibers, with no filtering or any other kind of optimization. In the case of ternary-amplitude signals (TAS), the bit rate of the probe signal needs to be N times larger than the one the pump signal, where N is an integer number greater than 2. It is shown that the power level distribution of TAS may be arbitrarily chosen by simply adjusting the power associated with the "bit-1" pump level; this is an interesting feature because it allows the BER of the TAS to be minimized for any kind of dominant noise. In fact, in one of the presented experiments the TAS generated by parametric amplification was propagated by a 40-km long standard fiber link of a field-trial network and BERs inferior to 3.5 10-15 were obtained. The low BER values obtained by the QAS and TAS generated by parametric amplification suggest that both of the techniques investigated in this work could be utilized in practical applications / Doutorado / Eletrônica, Microeletrônica e Optoeletrônica / Doutor em Engenharia Elétrica

Amplificadores paramétricos

Processamento óptico de sinais

Comunicações óticas

Fibras óticas

Parametric amplifiers

Optical signal processing

Optical communications

Fiber optics

All-Optical Signal Processing Using the Kerr Effect for Fiber-Based Sensors

Vanus, Benoit Yvon Eric

20 October 2021

All-optical signal processing has grown over the last decade due to the demand for high-speed and high-bandwidth data processing. The main objective of all-optical signal processing is to avoid signal conversions from the optical domain to electrical domain and then back to optical, which introduces noise and bottlenecks data transmission speeds. These conversions can be avoided by manipulating light using an optical medium, e.g. an optical fiber, and taking advantage of the nonlinear response of the medium's dipoles to an external electric field. Nonlinear effects arising from the third-order nonlinearities, such as the Kerr effect, allow for an intense light beam to modify the refractive index of a medium through which it propagates. As a consequence, the phase of the light beam changes as it propagates and new frequencies are generated; this phenomenon is referred to as self-phase modulation (SPM). Light's ability to modify not only its own properties but also the properties of other co-propagating beams has been widely applied in telecommunications to create integrated all-optical data regenerators. While optical fibers are mainly utilized to transmit data at extreme speeds, they can also act as sensors when considering the reflected signal as opposed to the transmitted signal. Surprisingly, most of the fiber sensing field relies on electrically-driven components for manipulating light and does not take advantage of all-optical signal processing capabilities. In this thesis, we demonstrate the use of the nonlinear Kerr effect to improve aspects of both fiber point and distributed sensing. These sensing scenarios respectively refer to the use of a fiber as a single sensing element, and to the detection of external perturbations continuously along the entire length of the fiber. The sensing improvement are obtained by first inducing a sinusoidal modulation on the light before it experiences self-phase modulation in a nonlinear medium, leading to the generation of optical sidebands. By judiciously adjusting the peak power of the light and extracting a specific sideband, multiple all-optical signal processing functions are achieved. First, high extinction ratio pulses can be generated by extracting a higher-order sideband, which allows for extending the sensing distance of distributed fiber-based sensors. The extinction ratio refers to the ratio between the pulse peak and pedestal powers. To quantify the generated extinction ratios, we develop a measurement technique based on a single-photon counter and measure a pulse exhibiting a 120 dB extinction ratio, which was originally created by an electro-optic modulator with a 20-dB extinction ratio. Second, all-optical peak power stabilization can be achieved by extracting the first-order SPM-generated sideband. We utilize this technique to stabilize the peak power of an optical pulse sent to a distributed fiber sensor. We demonstrate that this stabilization technique allows for the detection of applied vibrations that would otherwise remain buried in the background noise. Third, we demonstrate an all-optical scheme, based on sinusoidally-modulated light experiencing SPM, that enables the magnification of fluctuations in the peak power intensity of a pulsed signal. The light's peak power at the entrance of the nonlinear medium is adjusted to reach a power regime yielding a magnification factor of 2m+1, when extracting the mth-order SPM-generated sideband. Finally, we propose a new sensing scheme composed of two all-optical signal processing steps to allow for the detection of environmental perturbations previously too small to be detected by a given intensity-based fiber sensor.

Optical fibers

Fiber sensing

Kerr effect

Sensor

Signal processing

All-optical signal processing

Self-phase modulation

Distributed sensing

Sistema de monitoramento óptico banda larga direto para fabricação de filmes finos multicamadas com sincronização sensorless / Broadband direct optical monitoring system for multilayer thin film manufacturing with sensorless synchronization

Martins, André Luis

24 March 2011

Para a fabricação de filtros ópticos com característica espectral crítica, utiliza-se a tecnologia de filmes finos multicamadas, a qual exige o monitoramento e controle de espessura dos filmes com alta precisão. O sistema tradicional de monitoramento de espessura de filmes, baseado em cristal ressonante, não atende aos requisitos de precisão e repetibilidade do processo exigidos para a fabricação deste tipo de filtro. Já o monitoramento óptico, por sua vez, é um sistema que atende aos requisitos de fabricação destes filtros. Neste trabalho apresenta-se o desenvolvimento de um sistema automático de monitoramento óptico banda larga, para fabricação de filtros com filmes finos multicamadas, que se baseia na utilização de equipamentos ópticos de uso geral disponíveis no mercado. Para realizar análises de desempenho referentes exclusivamente ao algoritmo de automatização, um ambiente de simulação foi preparado, no qual os dados fornecidos pelo equipamento de aquisição de características ópticas durante a deposição efetiva foram substituídos por dados gerados por um algoritmo de simulação de crescimento do filme. Deste modo, o algoritmo de automatização e seus sistemas de segurança puderam ser exercitados. As simulações mostraram que o sistema proposto possui potencial para tornar mais preciso e repetitivo o processo de fabricação de filtros, de modo que atendam aos requisitos das aplicações especiais. / Optical filter manufacturing with critical spectral characteristics uses multilayer thin film technology, which demandas film thickness monitoring and control with high precision. Traditional monitoring systems based on oscillating crystal do not fulfill requirements of accuracy and process repeatability for manufacturing such type of filter. On the other hand, optical broadband monitoring system fulfills the manufacturing requirements to produce these filters. This work presents the development of a broadband optical monitoring system for multilayer thin film filters production, based on general optical equipment commercially available. In order to make the performance analysis related to automation algorithm, a simulation environment has been prepared, where the data supplied by optical data acquisition equipment has been replaced by simulating signals of film growing. Thus the automation algorithm and security systems could be worked. Simulations showed that the system has potential to improve the accuracy and repeatability of the manufacturing process so that the produced filters are able to fulfill the requirements of special applications.

Broadband optical monitoring

Espectrofotômetro

Filmes finos

Filtros ópticos multicamadas

Monitor óptico banda larga

Multilayer optical filters

Optical signal processing

Processamento de sinais ópticos

Spectrophotometer

Thin films