Investigation of Energy Coupling between Laser Diodes and Tapered Fibers, 2-D Case

Lee, Shun-Tien

30 June 2000

Abstract Optical fiber communications have been become one of the most popular researches since 1970s. In this field, there are many studies on the coupling between semiconductor lasers and fibers and many conclusions are demonstrated. In this thesis we build a 2-D numerical model to simulate energy coupling between laser diodes (LDs) and tapered optical fibers. Our model is based on the spectral domain integral equation (SDIE) formulation which is derived from Maxwell equations and the principle of mode matching. Through this numerical model we will be able to show the field distribution in LD waveguide junctions. We may also use this tool to study the coupling parameters such as the separation distance and tapered fiber geometry.

tapered fiber

mode matching method

spectral domain integral equation

coupling

Snapshot Spectral Domain Optical Coherence Tomography

Valdez, Ashley

January 2016

Optical coherence tomography systems are used to image the retina in 3D to allow ophthalmologists diagnose ocular disease. These systems yield large data sets that are often labor-intensive to analyze and require significant expertise in order to draw conclusions, especially when used over time to monitor disease progression. Spectral Domain Optical Coherence Tomography (SD-OCT) instantly acquires depth profiles at a single location with a broadband source. These systems require mechanical scanning to generate two- or three-dimensional images. Instead of mechanically scanning, a beamlet array was used to permit multiple depth measurements on the retina with a single snapshot using a 3x 3 beamlet array. This multi-channel system was designed, assembled, and tested using a 1 x 2 beamlet lens array instead of a 3 x 3 beamlet array as a proof of concept prototype. The source was a superluminescent diode centered at 840nm with a 45nm bandwidth. Theoretical axial resolution was 6.92um and depth of focus was 3.45mm. Glass samples of varying thickness ranging from 0.18mm to 1.14mm were measured with the system to validate that correct depth profiles can be acquired for each channel. The results demonstrated the prototype system performed as expected, and is ready to be modified for in vivo applicability.

Optical Coherence Tomography

retinal imaging

SDOCT

Snapshot

Spectral Domain

Optical Sciences

OCT

Performance Improvement of an Optical Coherence Tomography System by use of an Optical Pupil Slicer

Meade, Jeffrey

January 2011

Spectral domain optical coherence tomography (SD-OCT) is a dispersed interferometric technology used to obtain tomographic images, typically of tissue for medical applications. OCT is a competing technology with confocal microscopy (CM) and confocal fluorescent microscopy (CFM), which are both used for biopsy imaging for pathology as the gold standard. OCT offers several advantages over CM/CFM: it is able to acquire a full 3D image in a single pass, it requires little or no sample preparation time, and the axial (depth) and lateral (transverse) resolution are not dependent on one another. SD-OCT is limited in imaging depth to a few millimetres due to the quality performance of the spectrograph section of the instrument--that which determines the sensitivity of the SD-OCT system. In this thesis a design for an SD-OCT system is presented that is suitable for biopsy imaging for pathological studies, i.e. an OCT microscope. The purpose of this system is to provide a fast diagnosis to be made in a surgical environment to reduce the amount of tissue removed from a patient and lower the chance of a returned visit at a later date due to insufficient tissue removal. The secondary purpose of the SD-OCT microscope is to serve as a research testbed system for implementing novel hardware advancements. One such technology, called an optical pupil slicer (OPS), will be implemented in the instrument to improve the depth imaging performance of the SD-OCT system over conventional SD-OCT systems. The OPS is a device that generally improves the performance of a dispersive-type spectrograph by increasing the spectral resolution without a loss in throughput, thereby increasing the sensitivity of the SD-OCT system.

Optical Coherence Tomography

Slicer

Pupil

Spectral Domain

OCT

System Design Engineering

Performance Improvement of an Optical Coherence Tomography System by use of an Optical Pupil Slicer

Meade, Jeffrey

January 2011

Spectral domain optical coherence tomography (SD-OCT) is a dispersed interferometric technology used to obtain tomographic images, typically of tissue for medical applications. OCT is a competing technology with confocal microscopy (CM) and confocal fluorescent microscopy (CFM), which are both used for biopsy imaging for pathology as the gold standard. OCT offers several advantages over CM/CFM: it is able to acquire a full 3D image in a single pass, it requires little or no sample preparation time, and the axial (depth) and lateral (transverse) resolution are not dependent on one another. SD-OCT is limited in imaging depth to a few millimetres due to the quality performance of the spectrograph section of the instrument--that which determines the sensitivity of the SD-OCT system. In this thesis a design for an SD-OCT system is presented that is suitable for biopsy imaging for pathological studies, i.e. an OCT microscope. The purpose of this system is to provide a fast diagnosis to be made in a surgical environment to reduce the amount of tissue removed from a patient and lower the chance of a returned visit at a later date due to insufficient tissue removal. The secondary purpose of the SD-OCT microscope is to serve as a research testbed system for implementing novel hardware advancements. One such technology, called an optical pupil slicer (OPS), will be implemented in the instrument to improve the depth imaging performance of the SD-OCT system over conventional SD-OCT systems. The OPS is a device that generally improves the performance of a dispersive-type spectrograph by increasing the spectral resolution without a loss in throughput, thereby increasing the sensitivity of the SD-OCT system.

Optical Coherence Tomography

Slicer

Pupil

Spectral Domain

OCT

System Design Engineering

[en] ANALYSIS OF PROPAGATION OF SHORT ELECTRICAL PULSE BY THE SPECTRAL DOMAIN APPROACH / [pt] ANÁLISE DA PROPAGAÇÃO DE PULSOS ELÉTRICOS CURTOS EM LINHAS DE TRANSMISSÃO IMPRESSAS PELA ABORDAGEM DE DOMÍNIO ESPECTRAL

RICARDO ALBERTO OLIVARES VELIZ

02 August 2006

[pt] Neste trabalho se estuda a propagação de pulsos elétricos curtos em linhas de transmissão impressas, uniformes e não- uniformes, através de simulação por computador. Como a faixa de freqüências associada a estes pulsos, com duração e picossegundos, extende-se até várias centenas de giga Hertz, a caracterização das linhas de transmissão ao longo das quais os pulsos se propagam exige o rigor dos métodos de onda completa. Com este propósito é utilizada a Abordagem de Domínio Espectral (ADE) para rigorosamente considerar as características dos materiais e a geometria das linhas, na faixa de freqüência requerida, no cálculo das constantes de fase e de atenuação. A resposta a transientes é analisada no domínio do tempo empregando-se a Transformada de Fourier. É observado que a principal causa da distorção dos pulsos é a característica dispersiva das linhas; enquanto as perdas, devido aos materiais ou pelo descasamento de impedância no caso de linhas não-uniformes, só atenuam os sinais, sem deformá- los significativamente. Isto foi observado em linhas microstrips isoladas. Entretanto, em linhas microstrips acopladas um outro mecanismo de distorção que se agrega, e que é o dominante, é a distorção por acoplamento modal. É comprovado também, que a natureza dispersiva das linhas de transmissão pode ser usada, favoravelmente, para reformar pulsos assimétricos. Este último resultado encontra interessantes aplicações em Óptica. / [en] In this work, the propagation of short electrical pulse on uniform and non-uniform planar transmission lines is studied by means of computer simulation. As the frequency band associated with electrical pulses with duration of pico-seconds extends up to several hundreds of giga Hertz, the characterization of the transmission lines along which the pulses propagate requires full waves methods. With this purpose the Spectral Domain Approach (SDA) is used to rigorously consider the effects of the line material and geometry, in the frequency band required, to calculate the phase and attenuation constants. A Fourier Transform is used to analyse the transient response in the time domain. It is observed that the tranmission line dispersion is the main cause for distortion fo the pulses, while the losses - due to the materials or mismatching on non-uniform lines - are mainly responsible for signal attenuation. However, in coupled microstrip lines, distortion due to mode coupling was the dominant distortion mechanism. It is also observed that the dispersive nature of the transmission line can be used with advantage, through carefull choice of geometry and composition, to reshape asymetrical pulses. The results fo this study find applications on quasi-optical circuits and optical circuits short pulse generation.

[pt] LINHAS DE TRANSMISSAO

[en] TRANSMISSION LINES

[pt] PULSOS ELETRICOS

[en] ELECTRICAL PULSE

[pt] DOMINIO ESPECTRAL

[en] SPECTRAL DOMAIN

Desenvolvimento de algoritmos numéricos e interface gráfica aplicados à análise de guias de ondas planos através da abordagem de domínio espectral /

Menezes, João Paulo Crivellaro de

January 2020

Orientador: Claudio Kitano / Resumo: Sistemas ópticos operando em altas frequências utilizam modulação externa do laser, em especial através de moduladores baseados no efeito eletroóptico linear, onde se aplicam guias de ondas de dimensões reduzidas com eletrodos planares. Assim, é importante e conveniente determinar as propriedades e a distribuição do campo elétrico modulador de modo a conhecer outras características da estrutura, como resposta em frequência e potência de modulação. Neste trabalho, isto foi feito através do método de abordagem de domínio espectral. Contudo, este método apresenta imprecisões em estruturas com assimetria de eletrodos, aplicando-se então o método das imagens, clássico no eletromagnetismo, aliado à técnica de abordagem de domínio espectral. Esta nova abordagem permite a obtenção de funções de base adequadas à análise de parâmetros como o campo elétrico, assim como os demais parâmetros característicos dos guias de ondas planos. Este trabalho apresenta esta abordagem e seus resultados comparando-os à simples translação das funções de base para estruturas simétricas, validando a técnica proposta, bem como se propõe a desenvolver um conjunto de rotinas numéricas utilizando para isso o software Matlab. Através do processo de desenvolvimento das rotinas numéricas são apresentadas as dificuldades e metodologias de solução para implementação do método automatizado. Além de permitir a automatização de todo o processo de cálculo, minimizando a interferência humana, neste trabalho também é de... (Resumo completo, clicar acesso eletrônico abaixo) / Doutor

Guias de onda planos

Moduladores eletroópticos

Abordagem de domínio espectral.

Flat waveguide

Electrooptic modulators

Spectral domain approach

Macular Structure Parameters as an Automated Indicator of Paracentral Scotoma in Early Glaucoma / 黄斑部構造パラメータを用いた早期緑内障における傍中心暗点の自動検出

Kimura, Yugo

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第18875号 / 医博第3986号 / 新制||医||1008(附属図書館) / 31826 / 京都大学大学院医学研究科医学専攻 / (主査)教授 森田 智視, 教授 福山 秀直, 教授 大森 治紀 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

glaucoma

paracentral scotoma

ganglion cell layer

490

Analysis of the combinatory effect of uniaxial electrical and magnetic anisotropy on the input impedance and mutual coupling of a printed dipole antenna

Bouknia, M.L., Zebiri, C., Sayad, D., Elfergani, Issa T., Alibakhshikenari, M., Rodriguez, J., Abd-Alhameed, Raed, Falcone, F., Limiti, E.

27 May 2021

Yes / The main objective of this work is to investigate the combinatory effects of both uniaxial magnetic and electrical anisotropies on the input impedance, resonant length and the mutual coupling between two dipoles printed on an anisotropic grounded substrate. Three different configurations: broadside, collinear and echelon are considered for the coupling investigation. The study is based on the numerical solution of the integral equation using the method of moments through the mathematical derivation of the appropriate Green’s functions in the spectral domain. In order to validate the computing method and evaluated Matlab® calculation code, numerical results are compared with available literature treating particular cases of uniaxial electrical anisotropy; good agreements are observed. New results of dipole structures printed on uniaxial magnetic anisotropic substrates are presented and discussed, with the investigation of the combined electrical and magnetic anisotropies effect on the input impedance and mutual coupling for different geometrical configurations. The combined uniaxial (electric and magnetic) anisotropies provide additional degrees of freedom for the input impedance control and coupling reduction. / This work is part of the POSITION-II project funded by the ECSEL joint Undertaking under grant number Ecsel-7831132-Postitio-II-2017-IA,www. position-2.eu and partly funded by FCT/MCTES through national funds and when applicable co-funded EU funds under the project UIDB/50008/2020- UIDP/50008/2020. This work was also supported in part by the DGRSDT (General Directorate of Scientific Research and Technological Development) - MESRS (Ministry of Higher Education and Scientific Research), Algeria, and RTI2018-095499-B-C31, Funded by Ministerio de Ciencia, Innovación y Universidades, Gobierno de España (MCIU/AEI/FEDER,UE).

Spectral domain analysis

Uniaxial anisotropy

Input impedance

Mutual coupling

Dipole antenna

Segmentations of the intraretinal surfaces, optic disc and retinal blood vessels in 3D-OCT scans

Lee, Kyung Moo

01 May 2009

Optical coherence tomography (OCT) is a safe and non-invasive imaging technique providing high axial resolution. A spectral-domain OCT scanner capable of acquiring volumetric data of the retina is becoming an increasingly important modality in ophthalmology for the diagnosis and management of a variety of retinal diseases such as glaucoma, diabetic retinopathy and age related macular degeneration (AMD) which are major causes of a loss of vision. To analyze and track these ocular diseases, developments of the automated methods for detecting intraretinal layers, optic discs and retinal blood vessels from spectral-domain OCT scans are highly required recently. The major contributions of this thesis include: 1) developing a fast method that can automatically segment ten intraretinal layers in the spectral-domain macular OCT scan for the layer thickness analysis, 2) developing a method that can automatically segment the optic disc cup and neuroretinal rim in the spectral-domain OCT scan centered at the optic nerve head (ONH) to measure the cup-to-disc ratio, an important structural indicator for the progression of glaucoma, and 3) developing a method that can automatically segment the 3-D retinal blood vessels in the spectral-domain ONH-centered OCT scan to extract 3-D features of the vessels for the diagnosis of retinal vascular diseases.

3-D graph search

intraretinal surface

optic disc

retinal blood vessel

segmentation

Analysis of gyrobianisotropic media effect on the input impedance, field distribution and mutual coupling of a printed dipole antenna

Lamine Bouknia, M., Zebiri, C., Sayad, D., Elfergani, Issa, Matin, M., Alibakhshikenari, M., Alharbi, A.G., Hu, Yim Fun, Abd-Alhameed, Raed, Rodriguez, J., Falcone, F., Limiti, E.

17 May 2022

Yes / In this paper, we present an analytical study for the investigation of the effects of the magnetoelectric elements of a reciprocal and nonreciprocal bianisotropic grounded substrate on the input impedance, resonant length of a dipole antenna as well as on the mutual coupling between two element printed dipole array in three configuration geometries: broadside, collinear and echelon printed on the same material. This study examines also the effect of the considered bianisotropic medium on the electric and magnetic field distributions that has been less addressed in the literature for antenna structures. Computations are based on the numerical resolution, using the spectral method of moments, of the integral equation developed through the mathematical derivation of the appropriate spectral Green’s functions of the studied dipole configuration. Original results, for chiral, achiral, Tellegen and general bi-anisotropic media, are obtained and discussed with the electric and magnetic field distributions for a better understanding and interpretation. These interesting results can serve as a stepping stone for further works to attract more attention to the reciprocal and non-reciprocal Tellgen media in-depth studies.

Gyro-bianisotropy

Chiral

Achiral

Tellegen

Dipole antenna

Input impedance

Uniaxial anisotropy

Mutual coupling

Spectral domain

Method of moments