Development of a validation shape sensing algorithm in Python with predictive and automatedanalysis

Castellanos, Carlos

January 2021

Difficulties with wind turbines can arise during operation due to externalforces provoked by the wind. Calculating the deflection of the blades can beused to give break points for maintenance, design and/or monitoring purposes. Fiber Bragg Grating (FBG) sensors can be installed on the windblades to detect signals that can be reinterpreted as deflection in differentdirections. In this project a tool was developed that can take this information in real time to analyze critical issues which is important to save timeand operational and maintenance costs (O&M). To do so, a predictive model is used to anticipate the deflection in the blades caused by the impact ofthe wind in different orientations. The main purpose of this work is to showan algorithm that can transform optical signals from the FBG sensors into ashape calculator for the deflection for maintenance purposes. At the sametime, it is shown that this algorithm can be used as a forecast tool takinginto consideration the weather data.

python

FBG

deflection

wavelength

machine learning

forecast

Engineering and Technology

Teknik och teknologier

Mid-Wavelength Infrared Thermal Emitters using GaN/AIGaN Quantum Wells and Photonic Crystals / GaN/AlGaN 量子井戸とフォトニック結晶に基づく中波長赤外熱幅射光源の開発

Dongyeon, Kang

23 May 2018

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第21270号 / 工博第4498号 / 新制||工||1700(附属図書館) / 京都大学大学院工学研究科電子工学専攻 / (主査)教授 野田 進, 教授 藤田 静雄, 教授 川上 養一 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Thermal emission

Photonic crystals

GaN/AlGaN Quantum wells

Intersubband transition

Mid-wavelength infrared

500

Model-based analysis of fiber-optic extended-wavelength diffuse reflectance spectroscopy for nerve detection

Sun, Yu, 0000-0003-0048-8352

January 2022

Optical spectroscopy is a real-time technique that holds promise as a potential surgical guidance tool. Fiber-optic diffuse reflectance spectroscopy (DRS) is a technique capable of intraoperative tissue differentiation. The common DRS focuses on estimating chromophore concentrations in the visible (VIS) wavelength range (400-1000 nm), where spectroscopic features of the blood, pigments, and tissue densities are present between 400 and 700 nm. Recently, extended-wavelength DRS (EWDRS), which extends the spectral window from the VIS through the short wave-infrared region (SWIR) up to 1800 nm, has emerged as a promising approach for identifying nerves and nerve bundles due to the SWIR including robust tissue absorption features associated with nerve-tissue related chromophores, including lipids, water and collagen proteins. One potential application of EWDRS is guiding minimally invasive surgical techniques, such as laparoscopy, where inadvertent injury to pelvic autonomic nerves (PANs) is a primary complication that can result in over 70% of patients suffering long-term side effects, including urinary incontinence and sexual dysfunction. There is a need for objective laparoscopic surgical guidance to precisely identify PANs from other tissues, and an improved basis for EWDRS development could assist clinical translation. Prior development of Fiber-optic DRS for tissue classification in the VIS greatly benefited from the application of modeling techniques for simulation of optical measurements, analysis, and fiber-probe design. Model-based analysis can inform fundamental understanding of measured signals in different measurement scenarios, such as the varying tissue morphologies possible in laparoscopic procedures, and guide application-specific fiber-probe design through comparison of unique illumination/collection geometries; however, the demonstration of these approaches in EWDRS is not widely reported. This dissertation focuses on the advancement of platforms for model-driven analysis of EWDRS for nerve identification. In order to advance the current state of EWDRS, a model-based characterization platform for analysis of a custom-developed fiber-optic EWDRS system was developed in Aim 1, which demonstrated agreement between data collected from optical phantoms, ex vivo microsurgical model, and Monte Carlo (MC) computational simulations of EWDRS measurements. In Aim 2, the model-based platform was used to perform a detailed analysis of two similar EWDRS fiber-optic probes, which indicated subtle differences in the depth-dependent measurement performance. Finally, in Aim 3, the custom EWDRS was prepared for adapting laparoscopic use to demonstrate laparoscopic measurement feasibility, including evaluation of placement variance and customized EWDRS package for short-distance transportation. The successful completion of this dissertation will enable improved analyses of EWDRS devices for a variety of future intraoperative applications. / Bioengineering

Biomedical engineering

Optics

Monte Carlo model

Nerve identification

Optical phantom

Low-Resolution Infrared and High-Resolution Visible Image Fusion Based on U-NET

Lin, Hsuan

11 August 2022

No description available.

Electrical Engineering

Image Fusion

Super-Resolution

Infrared Image

Visible Wavelength Image

Convolutional Neural Network

Calibration of the UMass Advanced Multi-Frequency Radar

Mclinden, Matthew

01 January 2010

The Advanced Multi-Frequency Radar is a three-frequency system designed and built by the University of Massachusetts Microwave Remote Sensing Lab (MIRSL). The radar has three frequencies, Ku-band (13.4 GHz), Ka-band (35.6 GHz), and W-band (94.92GHz). The additional information gained from additional frequencies allows the system to be sensitive to a wide range of atmospheric and precipitation particle sizes, while increasing the ability to derive particle microphysics from radar retrievals. This thesis details the calibration of data from the Canadian CloudSat/CALIPSO Validation Project (C3VP) held during January 2007 in Ontario, Canada. The calibration used internal calibration path data and was confirmed through comparison of precipitation reflectivity with an Environment Canada radar. The calibrated data was then used to estimate the median mass diameter of precipitating snow from a high-priority C3VP data set. This median mass diameter retrieval was compared to the results from a local ground instrument, the Snow Video Imager (SVI), showing good agreement.

Radar

Calibration

Dual-Wavelength Ratio

Snow

Electromagnetism

Atmospheric Sciences

Electromagnetics and Photonics

Signal Processing

An Improved Flexible Neutron Detector For Powder Diffraction Experiments

McKnight, Thomas Kevin

08 July 2005

Large amounts of money are being applied to the construction of the next generation of spallation sources for neutron scattering. Neutron powder diffraction instruments will be an important element of these facilities and the incorporation of detectors into these instruments with a high neutron capture efficiency is desirable. A new detector design named the Flexible Embedded Fiber Detector (FEFD) has been developed and tested for this thesis. This detector is based on wavelength shifting fibers embedded in a zinc-sulfide lithium-fluoride based scintillator. The virtue of this design is that the detecting surface can be curved around the Debye-Scherrer rings. This virtue is lacking in other detector designs, making them more complex and poorer in performance than our FEFD detectors. Monte Carlo calculations were performed to determine the neutron capture efficiencies of our FEFD detectors, which proved to be much higher than those of the proposed powder diffractometer design for the Spallation Neutron Source and about equal with the efficiency for the ISIS powder diffractometer design. Four FEFD detector prototypes were then fabricated and tested at the Intense Pulsed Neutron Source at Argonne National Laboratory. We find that our measured and calculated relative efficiencies are in good agreement.

neutron diffraction

powder diffraction

neutron detector

zinc sulfide

wavelength shifting fiber

Debye Scherrer

Astrophysics and Astronomy

Physics

Improving Routing Efficiency, Fairness, Differentiated Servises And Throughput In Optical Networks

ZHOU, BIN

01 January 2006

Wavelength division multiplexed (WDM) optical networks are rapidly becoming the technology of choice in next-generation Internet architectures. This dissertation addresses the important issues of improving four aspects of optical networks, namely, routing efficiency, fairness, differentiated quality of service (QoS) and throughput. A new approach for implementing efficient routing and wavelength assignment in WDM networks is proposed and evaluated. In this approach, the state of a multiple-fiber link is represented by a compact bitmap computed as the logical union of the bitmaps of the free wavelengths in the fibers of this link. A modified Dijkstra's shortest path algorithm and a wavelength assignment algorithm are developed using fast logical operations on the bitmap representation. In optical burst switched (OBS) networks, the burst dropping probability increases as the number of hops in the lightpath of the burst increases. Two schemes are proposed and evaluated to alleviate this unfairness. The two schemes have simple logic, and alleviate the beat-down unfairness problem without negatively impacting the overall throughput of the system. Two similar schemes to provide differentiated services in OBS networks are introduced. A new scheme to improve the fairness of OBS networks based on burst preemption is presented. The scheme uses carefully designed constraints to avoid excessive wasted channel reservations, reduce cascaded useless preemptions, and maintain healthy throughput levels. A new scheme to improve the throughput of OBS networks based on burst preemption is presented. An analytical model is developed to compute the throughput of the network for the special case when the network has a ring topology and the preemption weight is based solely on burst size. The analytical model is quite accurate and gives results close to those obtained by simulation. Finally, a preemption-based scheme for the concurrent improvement of throughput and burst fairness in OBS networks is proposed and evaluated. The scheme uses a preemption weight consisting of two terms: the first term is a function of the size of the burst and the second term is the product of the hop count times the length of the lightpath of the burst.

optical networks

wavelength division multiplexing

optical burst switched networks

Computer Sciences

Engineering

Excitation Wavelength Dependent Response of a Biluminescent-Fluorescent Emitter Blend

Kirch, Anton

21 July 2022

Diese Arbeit untersucht Verhältnisse von Populationsdichten angeregter Spinzustände in einem System bestehend aus einem bilumineszenten (NPB) und einem fluoreszierenden (DCJTB) Emittermaterial. Beide organische Luminophore werden zur Unterdrückung nicht strahlender Relaxation in eine Matrix aus PMMA eingebettet und zeigen daher sowohl strahlende Triplettals auch Singulettemission bei Raumtemperatur. Mithilfe verschiedener LED- und Filterkombinationen wird das Verhältnis von verzögerter zu prompter Emission bei unterschiedlichen Anregungswellenlängen im Bereich zwischen 340nm und 420nm studiert. Dieser Bereich entspricht dem Überlapp der Absorptionslinien beider Emittermoleküle. Der Anteil der Triplett- an der Gesamtemission des Systems variiert innerhalb des angegebenen Wellenlängenbereichs um fast zwei Größenordnungen. Bei der Untersuchung des Effektes wird weiterhin ein doppelter Förstertransfer von beiden angeregten Spinzuständen des Biluminophors zum Singulettzustand des Fluorophors nachgewiesen. Besonders einprägsam erscheint dabei, dass beide Transfers mit bloßem Auge zu beobachten sind, obwohl sie auf völlig unterschiedlichen Zeitskalen ablaufen.:1 Introduction 2 Physics of Organic Luminophores 3 Experimental 4 Data Evaluation Tools 5 Wavelength Dependent Excitation 6 Dual State Förster Resonance Energy Transfer 7 Concluding Thoughts and Outlook Bibliography List of Abbreviations List of Tables List of Figures

info:eu-repo/classification/ddc/510

ddc:510

Growth and Characterization of Semiconductor Quantum Wires

Cui, Kai

12 1900

<p> Semiconductor quantum wire (QWR) structure is a promising candidate for potential applications in long wavelength laser devices. In this thesis, the investigations were focused on the growth and characterization on the structural and optical properties of InAs quantum wires deposited on InGaAlAs lattice matched with InP substrate by gas source molecular beam epitaxy. </p> <P> The practical growth parameters were first determined by studying the samples containing single InAs layer embedded within Ino.s3Gll{)_37Alo.10As barrier layers. These parameters were then employed for fabricating multilayer quantum wires with different (1) spacer layer thicknesses; (2) quantum wire layer thicknesses; and (3) different Al concentrations in the spacer/barrier layer materials. </P> <P>Structural properties of the quantum wires were characterized by (scanning) transmission electron microscopy based techniques. The composition variation, elastic field and the variation of QWR stacking patterns in multilayer samples were qualitatively studied through diffraction contrast imaging. Quantification of the In distribution in individual QWRs and the QWR-induced In composition modulation in barrier layers were obtained by electron energy loss spectrometry and energy dispersive X-ray spectrometry, respectively. These experimentally observed structural features were explained through finite element simulations. </P> <P> The optical properties of the QWR structures were studied by photoluminescence. Optical emission at room temperature was achieved from selected multilayer QWR samples after etching and rapid thermal annealing. The emission wavelength ranging from 1.53 to 1.72 μm makes the QWR structure suitable candidates for laser device applications. </P> / Thesis / Doctor of Philosophy (PhD)

InGaA1As, InP, variation, elastic field

Design, Fabrication and Analysis of Broadly Tunable Asymmetric Multiple Quantum Well Coupled Cavity Diode Lasers

Khan, Ferdous Karim

01 1900

<p>A detailed analysis of coupled cavity semiconductor lasers with asymmetric multiple quantum well (AMQW) active regions is presented in this thesis. The analysis involved design, fabrication, characterization, and simulation of these devices. Although the coupled cavity devices can be multi sectioned, the devices discussed in this thesis are two sectioned.</p><p> A below threshold model for an AMQW coupled cavity device is developed. Non-linear fits of the below threshold spectral data to that obtained from the model were used to extract optimized device parameters. These fits helped to create an understanding of the operation of the devices and paved the way for improved device performance. Optimized device parameters obtained from the below threshold model were later used as input parameters in the development of an above threshold model. This model verified the wavelength selection mechanism employed by coupled cavity diode lasers and predicted the longitudinal modes for sets of injection currents.</p><p> Optical coherence tomography (OCT) is an application where much interest has recently been drawn. The coupled cavity devices fabricated in this work applied with proper modulation of the injection currents and followed by subsequent time averaging have demonstrated short coherence length (-15 μm) and can be an excellent source for synthesized OCT. Rapid wavelength switching (-70 ns, the measurement was limited by detector response time) over the whole range has also been experimentally shown. Because of the high speed (relative to mechanical) wavelength switching ability, AMQW coupled cavity devices have the potential for applications requiring real time measurements including real time synthesized OCT.</p> / Thesis / Doctor of Philosophy (PhD)

coupled cavity semiconductor laser

asymmetric multiple quantum well

optical coherence technology

wavelength switching