Global ETD Search

181	Theoretical studies of optical absorption in low-bandgap polymers / Teoretiska studier av optisk absorption i polymerer med låga bandgap Karlsson, Daniel January 2005 (has links) The absorption spectra of a recently designed low-bandgap conjugated polymer has been studied using the semi-empirical method ZINDO and TDDFT/B3LYP/6-31G. The vertical excitation energies have been calculated for monomer up to hexamer. Two main absorption peaks can be seen, the one largest in wavelength corresponding to a HOMO to LUMO transition, and one involving higher order excitations. TDDFT results are red-shifted compared to the ZINDO results. Comparison with experiment yields that short conjugation lengths are dominating. This is possibly due to steric interactions between polymer chains, breaking the conjugation length. Such effects are also studied. ZINDO Density functional theory Hartree Fock method Low bandgap polymers Absorption spectra Semi empirical methods Plastic solar cells Computational physics Beräkningsfysik
182	An accurate, trimless, high PSRR, low-voltage, CMOS bandgap reference IC Gupta, Vishal 05 July 2007 (has links) Bandgap reference circuits are used in a host of analog, digital, and mixed-signal systems to establish an accurate voltage standard for the entire IC. The accuracy of the bandgap reference voltage under steady-state (dc) and transient (ac) conditions is critical to obtain high system performance. In this work, the impact of process, power-supply, load, and temperature variations and package stresses on the dc and ac accuracy of bandgap reference circuits has been analyzed. Based on this analysis, the a bandgap reference that 1. has high dc accuracy despite process and temperature variations and package stresses, without resorting to expensive trimming or noisy switching schemes, 2. has high dc and ac accuracy despite power-supply variations, without using large off-chip capacitors that increase bill-of-material costs, 3. has high dc and ac accuracy despite load variations, without resorting to error-inducing buffers, 4. is capable of producing a sub-bandgap reference voltage with a low power-supply, to enable it to operate in modern, battery-operated portable applications, 5. utilizes a standard CMOS process, to lower manufacturing costs, and 6. is integrated, to consume less board space has been proposed. The functionality of critical components of the system has been verified through prototypes after which the performance of the complete system has been evaluated by integrating all the individual components on an IC. The proposed CMOS bandgap reference can withstand 5mA of load variations while generating a reference voltage of 890mV that is accurate with respect to temperature to the first order. It exhibits a trimless, dc 3-sigma accuracy performance of 0.84% over a temperature range of -40°C to 125°C and has a worst case ac power-supply ripple rejection (PSRR) performance of 30dB up to 50MHz using 60pF of on-chip capacitance. All the proposed techniques lead to the development of a CMOS bandgap reference that meets the low-cost, high-accuracy demands of state-of-the-art System-on-Chip environments. Lateral PNP Trimming System-on-Chip SoC Regulated reference PSRR Output impedance Accuracy Trimless Bandgap references Low-voltage CMOS Analog circuit design
183	Design of analog circuits for extreme environment applications Najafizadeh, Laleh 21 August 2009 (has links) This work investigates the challenges associated with designing silicon-germanium (SiGe) analog and mixed-signal circuits capable of operating reliably in extreme environment conditions. Three extreme environment operational conditions, namely, operation over an extremely wide temperature range, operation at extremely low temperatures, and operation under radiation exposure, are considered. As a representative for critical analog building blocks, bandgap voltage reference (BGR) circuit is chosen. Several architectures of the BGRs are implemented in two SiGe BiCMOS technology platforms. The effects of wide-temperature operation, deep cryogenic operation, and proton and x-ray irradiation on the performance of BGRs are investigated. The impact of Ge profile shape on BGR's wide-temperature performance is also addressed. Single-event transient response of the BGR circuit is studied through microbeam experiments. In addition, proton radiation response of high-voltage transistors, implemented in a low-voltage SiGe platform, is investigated. A platform consisting of a high-speed comparator, digital-to-analog (DAC) converter, and a high-speed flash analog-to-digital (ADC) converter is designed to facilitate the evaluation of the extreme environment capabilities of SiGe data converters. Room temperature measurement results are presented and predictions on how temperature and radiation will impact their key electrical properties are provided. Analog circuits SiGe Extreme environment Bandgap voltage references Heterojunction bipolar transistor Silicon germanium Low temperature operation Single-event Radiation effects Cryoelectronics Materials Effect of radiation on Silicon alloys
184	Capteur de vision CMOS à réponse insensible aux variations de température Zimouche, Hakim 01 September 2011 (has links) (PDF) Les capteurs d'images CMOS sont de plus en plus utilisés dans le domaine industriel : la surveillance, la défense, le médical, etc. Dans ces domaines, les capteurs d'images CMOS sont exposés potentiellement à de grandes variations de température. Les capteurs d?images CMOS, comme tous les circuits analogiques, sont très sensibles aux variations de température, ce qui limite leurs applications. Jusqu'à présent, aucune solution intégrée pour contrer ce problème n'a été proposée. Afin de remédier à ce défaut, nous étudions, dans cette thèse, les effets de la température sur les deux types d'imageurs les plus connus. Plusieurs structures de compensation sont proposées. Elles reprennent globalement les trois méthodes existantes et jamais appliquées aux capteurs d'images. La première méthode utilise une entrée au niveau du pixel qui sera modulée en fonction de l'évolution de la température. La deuxième méthode utilise la technique ZTC (Zero Température Coefficient). La troisième méthode est inspirée de la méthode de la tension de référence bandgap. Dans tous les cas, nous réduisons de manière très intéressante l'effet de la température et nous obtenons une bonne stabilité en température de -30 à 125°C. Toutes les solutions proposées préservent le fonctionnement initial de l'imageur. Elles n'impactent également pas ou peu la surface du pixel [SPI:OTHER] Engineering Sciences/Other Capteur d'image CMOS Grande Dynamique Compensation en Température Tension de Référence Bandgap CMOS
185	Some Aspects of Advanced Technologies and Signal Integrity Issues in High Frequency PCBs, with Emphasis on Planar Transmission Lines and RF/Microwave Filters Mbairi, Felix D. January 2007 (has links) The main focus of this thesis is placed on high frequency PCB signal Integrity Is-sues and RF/Microwave filters using EBG structures. From the signal Integrity aspect, two topics were mainly discussed. On one hand, the effect of increasing frequency on classical design rules for crosstalk reduction in PCBs was investigated experimentally and by full-wave simulations. An emphasis was placed on the 3×W spacing rule and the use of guard traces. Single-ended and differential transmission lines were considered. S-parameter measurements and simu-lations were carried out at high-frequency (up to 20 GHz). The results emphasize the necessity to reevaluate traditional design rules for their suitability in high frequency applications. Also, the impacts of using guard traces for high frequency crosstalk re-duction were clearly pointed out. On the other hand, the effect of high loss PCB ma-terials on the signal transmission characteristics of microstrip lines at high frequency (up to 20 GHz) was treated. Comparative studies were carried out on different micro-strip configurations using standard FR4 substrate and a high frequency dielectric ma-terial from Rogers, Corporation. The experimental results highlight the dramatic im-pact of high dielectric loss materials (FR4 and solder mask) and magnetic plating metal (nickel) on the high frequency signal attenuation and loss of microstrip trans-mission lines. Besides, the epoxy-based SU8 photoresist was characterized at high frequency (up to 50 GHz) using on-wafer conductor-backed coplanar waveguide transmission lines. A relative dielectric constant of 3.2 was obtained at 30 GHz. Some issues related to the processing of this material, such as cracks, hard-skin, etc, were also discussed. Regarding RF/Microwave filters, the concept of Electromagnetic Band Gap (EBG) was used to design and fabricate novel microstrip bandstop filters using periodically modified substrate. The proposed EBG structures, which don’t suffer conductor backing issues, exhibit interesting frequency response characteristics. The limitations of modeling and simulation tools in terms of speed and accuracy are also examined in this thesis. Experiments and simulations were carried out show-ing the inadequacies of the Spice diode model for the simulations in power electronics. Also, an Artificial Neural Network (ANN) model was proposed as an alternative and a complement to full-wave solvers, for a quick and sufficiently accurate simulation of interconnects. A software implementation of this model using Matlab’s ANN toolbox was shown to considerably reduce (by over 800 times) the simulation time of microstrip lines using full-wave solvers such as Ansoft’s HFSS and CST’s MWS. Finally, a novel cooling structure using a double heatsink for high performance electronics was presented. Methods for optimizing this structure were also discussed. / QC 20100809 Signal integrity crosstalk guard trace PCB transmission line loss high frequency measurement dielectric SU-8 electromagnetic bandgap microwave filter Elektroteknik, elektronik och fotonik
186	High Gain DC-DC and Active Power Decoupling Techniques for Photovoltaic Inverters January 2017 (has links) abstract: The dissertation encompasses the transformer-less single phase PV inverters for both the string and microinverter applications. Two of the major challenge with such inverters include the presence of high-frequency common mode leakage current and double line frequency power decoupling with reliable capacitors without compromising converter power density. Two solutions are presented in this dissertation: half-bridge voltage swing (HBVS) and dynamic dc link (DDCL) inverters both of which completely eliminates the ground current through topological improvement. In addition, through active power decoupling technique, the capacitance requirement is reduced for both, thus achieving an all film-capacitor based solution with higher reliability. Also both the approaches are capable of supporting a wide range of power factor. Moreover, wide band-gap devices (both SiC and GaN) are used for implementing their hardware prototypes. It enables the switching frequency to be high without compromising on the converter efficiency. Also it allows a reduced magnetic component size, further enabling a high power density solution, with power density far beyond the state-of-the art solutions. Additionally, for the transformer-less microinverter application, another challenge is to achieve a very high gain DC-DC stage with a simultaneous high conversion efficiency. An extended duty ratio (EDR) boost converter which is a hybrid of switched capacitors and interleaved inductor technique, has been implemented for this purpose. It offers higher converter efficiency as most of the switches encounter lower voltage stress directly impacting switching loss; the input current being shared among all the interleaved converters (inherent sharing only in a limited duty ratio), the inductor conduction loss is reduced by a factor of the number of phases. Further, the EDR boost converter has been studied for both discontinuous conduction mode (DCM) operations and operations with wide input/output voltage range in continuous conduction mode (CCM). A current sharing between its interleaved input phases is studied in detail to show that inherent sharing is possible for only in a limited duty ratio span, and modification of the duty ratio scheme is proposed to ensure equal current sharing over all the operating range for 3 phase EDR boost. All the analysis are validated with experimental results. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2017 Electrical engineering Active power decoupling High gain boost PV transformerless inverter Sensor-less current sharing Switched capacitor Wide bandgap based inverter
187	Photonic Crystal Fiber as a Robust Raman Biosensor Khetani, Altaf January 2016 (has links) This thesis focuses on the investigation and development of an integrated optical biosensor based on enhanced Raman techniques that will provide label-free detection of biomolecules. This is achieved by using hollow core photonic crystal fibers (HC-PCF), nanoparticles, or both. HC-PCF is a unique type of optical fiber, with continuous ‘channels’ of air (typically) running the entire length. The channels serve to confine electromagnetic waves in the core of the fiber, and tailor its transmission properties. Using HC-PCF as a biosensor requires development of a robust technique to fill hollow-core photonic crystal fibers. Though several groups have reported selective filling of HC-PCF’s core, the processes are cumbersome and limit the choice of liquid to avoid multimode behavior. In my Master’s thesis, I presented a simple technique to non-selectively fill all the HC-PCF channels with samples. The non-selective filling preserves the photonic bandgap property of the fiber, and yields an extremely strong interaction of light and the sample that produces considerable enhancement of the Raman signal from the analyte. Up to now, non-selective filling was accomplished through capillary action and it delivered a Raman signal enhancement of approximately 30-fold, which is not sensitive enough to detect biomolecules at the clinical level. Moreover, there were issues of reliability and reproducibility, due to evaporation, filling and coupling light into the fiber. The objective of this PhD research was to overcome these problems by developing a robust optical fiber platform based on Raman spectroscopy that can be used in a clinical setting. I initially focused on heparin, an important blood anti-coagulant that requires precise monitoring and control in patients undergoing cardiac surgery or dialysis. Since the Raman spectra of heparin-serum mixtures exhibits Raman peaks of heparin with poor signal-to-noise ratios, I concentrated on enhancing the heparin Raman signal and filtering out the spectral background of the serum to improve detection sensitivity. Reaching maximum enhancement of the Raman signal required a strong interaction of light and analyte, which can be achieved by using hollow core photonic crystal fiber as I had used in my Master’s research. Using a small piece of HC-PCF I was able to reach an enhancement in the heparin Raman signal of greater than 90-fold. With this degree of enhancement, I was able to successfully detect and monitor heparin in serum at clinical levels, something that had never been accomplished previously. After developing HC-PCF as a Raman signal enhancer, I focused on making the HC-PCF sensor robust, reliable and reusable. This was achieved by integrating the HC-PCF with a differential pressure system that allowed effective filling, draining and refilling of the samples in an HC-PCF, under identical optical conditions. To demonstrate the device’s detection capabilities, various concentrations of aqueous ethanol and isopropanol, followed by different concentrations of heparin and adenosine in serum, were successfully monitored. To further improve the sensitivity of the HC-PCF based Raman sensor, I incorporated surface enhanced Raman scattering (SERS), by introducing nanoparticles into the HC-PCF fibers. The research focused on determining the optimal volume and size of silver nanoparticles to achieve maximum enhancement of the Raman signal in the HC-PCF. The HC-PCF enhanced the Raman signal of Rhodamine 6G (R6G) approximately 90-fold. In addition, the optimal size and volume of AgNP enhanced the Raman signal of R6G approximately 40-fold, leading to a total enhancement of approximately 4,000 in HC-PCF. This was then used to demonstrate the application of a SERS based HC-PCF sensing platform in monitoring adenosine (a clinically important molecule), as well as malignant cells such as leukemia. Finally, I used hollow core crystal fibers to significantly enhance the efficiency of two-photon photochemistry. Although two-photon photochemical reactions are difficult to achieve with a small volume, I accomplished it by using a novel platform of HC-PCF to efficiently execute the two-photon induced photodecarbonylation reaction of cyclopropenone 1, and its conversion to the corresponding acetylene. The simple optical design configuration involved coupling an 800-nm tsunami laser to a short piece of HC-PCF filled with the sample. This allowed me to increase the efficiency of two-photon induced photochemistry by 80-fold, compared to a conventional spectrophotometer cuvette. Thus, this work leads to the use of HC-PCFs to more effectively study two-photon induced photochemistry processes, which was limited due to the difficulty of detecting photochemical events with a small excitation volume. hollow core photonic crystal fiber biosensor optical sensor Raman spectroscopy PCF biological sensing and sensors surface-enhanced SERS bandgap fiber cell analysis Raman scattering
188	Characterization Techniques and Optimization Principles for Multi-Junction Solar Cells and Maximum Long Term Performance of CPV Systems Yandt, Mark January 2017 (has links) Two related bodies of work are presented, both of which aim to further the rapid development of next generation concentrating photovoltaic systems using high efficiency multi junction solar cells. They are complementary since the characterization of commercial devices and the systematic application of design principles for future designs must progress in parallel in order to accelerate iterative improvements. First addressed, is the field characterization of state of the art concentrating photovoltaic systems. Performance modeling and root cause analysis of deviations from the modeling results are critical for bringing reliable high value products to the market. Two complementary tools are presented that facilitate acceleration of the development cycle. The “Dynamic real-time I V Curve Measurement System…” provides a live picture of the current-voltage characteristics of a CPV module. This provides the user with an intuitive understanding of how module performance responds under perturbation. The “Shutter technique for noninvasive individual cell characterization in sealed concentrating photovoltaic modules,” allows the user to probe individual cell characteristics within a sealed module. This facilitates non-invasive characterization of modules that are in situ. Together, these tools were used to diagnose the wide spread failure of epoxy connections between the carrier and the emitter of bypass diodes installed in sealed commercial modules. Next, the optimization principals that are used to choose energy yield maximizing bandgap combinations for multi-junction solar cells are investigated. It is well understood that, due to differences in the solar resource in different geographical locations, this is fundamentally a local optimization problem. However, until now, a robust methodology for determining the influences of geography and atmospheric content on the ideal design point has not been developed. This analysis is presented and the influence of changing environment on the representative spectra that are used to optimize bandgap combinations is demonstrated. Calculations are confirmed with ground measurements in Ottawa, Canada and the global trends are refined for this particular location. Further, as cell designers begin to take advantage of more flexible manufacturing processes, it is critical to know if and how optimization criteria must change for solar cells with more junctions. This analysis is expanded to account for the differences between cells with up to 8 subcell bandgaps. A number of software tools were also developed for the Sunlab during this work. A multi-junction solar cell model calibration tool was developed to determine the parameters that describe each subcell. The tool fits a two diode model to temperature dependent measurements of each subcell and provides the fitting parameters so that the performance of multi-junction solar cells composed of those subcells can be modeled for real world conditions before they are put on-sun. A multi-junction bandgap optimization tool was developed to more quickly and robustly determine the ideal bandgap combinations for a set of input spectra. The optimization process outputs the current results during iteration so that they may be visualized. Finally, software tools that compute annual energy yield for input multi-junction cell parameters were developed. Both a brute force tool that computes energy harvested at each time step, and an accelerated tool that first bins time steps into discrete bins were developed. These tools will continue to be used by members of the Sunlab. Photovoltaics Solar Cells Live IV curve Shutter Technique Representative Spectrum Representative Atmospheric Parameters Multi Junction Solar Cells Solar Cell Optimization Bandgap Optimisation Concentrating Photovoltaic Systems
189	Combinatorial Pulsed Laser Deposition Employing Radially-Segmented Targets: Exploring Orthorhombic (InxGa1−x)2O3 and (AlxGa1−x)2O3 Towards Superlattice Heterostructures Kneiß, Max 16 December 2020 (has links) Die vorliegende Arbeit beschreibt den Verlauf der Forschung von der Entwicklung einer neuartigen Methode der gepulsten Laser-Plasmaabscheidung (PLD) über die Untersuchung der ternären In- und Al-Legierungssysteme von metastabilem orthorhombischen κ-Ga2O3 auf der Basis dieser Methode hin zu Multi-Quantengraben (QW) Supergitter (SL) Heterostrukturen für transparente Quantengrabeninfrarotphotodetektoren (QWIPs). Im ersten Teil wird die Methode, welche vertical continuous composition spread (VCCS) PLD genannt wird, eingeführt und am MgxZn1−xO Legierungssystem erprobt. Die Methode erlaubt die Kontrolle der Komposition von Dünnﬁlmen über die radiale Position des PLD Laserspots auf der Targetoberﬂäche. Das ist eine wichtige Voraussetzung für die Bestimmung der kompositionsabhängigen Eigenschaften der Legierungssysteme und für präzise Proﬁle der physikalischen Eigenschaften in Wachstumsrichtung für das Design von Bauelementen. Die Dünnﬁlme mit 0 ≤ x ≤ 0.4 zeigen die gleichen Eigenschaften wie solche, die mit Standard-PLD abgeschieden wurden. Numerische Modelle werden präsentiert, welche die Dünnﬁlmkomposition exakt vorhersagen. Im zweiten Teil werden κ-Ga2O3 Dünnﬁlme durch die Beigabe von Zinn während des PLD Prozesses stabilisiert. Die Dünnﬁlme weisen hohe kristalline Qualität, glatte Oberﬂächen und große Bandlücken (Eg ≈ 4.9 eV) auf. Ein Wachstumsmodell wird präsentiert, welches Zinn als Oberﬂächenschicht beschreibt. Im dritten Teil werden die In- und Al-Legierungssysteme von κ-Ga2O3 mittels VCCS PLD untersucht. Die Löslichkeitsgrenzen xIn <~ 0.35 und xAl <~ 0.65 sind die höchsten bislang berichteten. In- und out-of-plane Gitterkonstanten wurden in Abhängigkeit der Zusammensetzung bestimmt und Eg konnte von 4.1 eV bis 6.4 eV variiert werden. Die Position des Valenzbandmaximums wird als unabhängig von der Komposition gezeigt, womit die Variation in Eg den Leitungsbandunterschieden gleicht und Detektionsbereiche vom fernen IR bis in das Sichtbare für QWIP-Anwendungen bedeutet. Berechnungen anhand dieser Ergebnisse ergeben Polarisationsladungsdichten an Grenzﬂächen von Heterostrukturen gleich oder höher derer im etablierten AlGaN/GaN System, welche wichtig zur Polarisationsdotierung zur Besetzung des Grundzustandes in QWIPs sind. Dies bestätigt das große Potential der κ-Phase. Im letzten Teil werden erste kohärent gewachsene κ-(AlxGa1−x)2O3/Ga2O3 SL Strukturen untersucht. Glatte Grenzﬂächen im Bereich weniger Monolagen werden gezeigt und es konnten kritische Dicken für die κ-Ga2O3 QW Schichten bestimmt werden, die für QWIP-Anwendungen genügen. / The presented thesis describes the research path from the development of a novel pulsed laser deposition (PLD) technique over the exploration of the ternary In- and Al-alloy systems of metastable orthorhombic κ-Ga2O3 employing this technique towards multi-quantum well (QW) superlattice (SL) heterostructures for solar-blind quantum well infrared photodetector (QWIP) applications. In the ﬁrst part, the PLD technique called vertical continuous composition spread (VCCS) PLD employing radially-segmented targets is established and tested on the well-known MgxZn1−xO alloy system. The technique enables direct control of the chemical composition of thin ﬁlms by a variation of the radial position of the PLD laser spot on the target surface. This is a prerequisite for a discrete compositional screening of alloy properties and the exact tailoring of physical parameters in growth direction for heterostructure device design. The resulting thin ﬁlms with 0 ≤ x ≤ 0.4 exhibit the same quality as thin ﬁlms deposited by standard PLD and numerical models are presented that precisely predict the thin ﬁlm composition. In the second part, κ-Ga2O3 thin ﬁlms are stabilized by the addition of tin in the PLD process. The thin ﬁlms show a high crystalline quality, smooth surfaces and large bandgaps (Eg ≈ 4.9 eV). A growth model is proposed based on tin acting as surfactant. In the third part, the In- and Al-alloy systems of κ-Ga2O3 are explored by VCCS PLD. Solubility limits of xIn <~ 0.35 and xAl <~ 0.65 are the highest reported to date. In- and out-of-plane lattice constants were determined as function of alloy composition and bandgap engineering from 4.1 eV to 6.4 eV is feasible within these limits. The energetic position of the valence band maximum was found independent on chemical composition such that the change in bandgap equals the conduction band oﬀset rendering wavelength ranges from far IR to the visible spectral range in QWIP applications possible. Calculations based on these results found polarization charge densities at the interfaces of corresponding heterostructures on par or larger than for the established AlGaN/GaN system important for polarization doping to populate the ground state in QWIPs. This corroborates the high potential of the κ-phase. In the last part, ﬁrst coherently grown κ-(AlxGa1−x)2O3/Ga2O3 SL heterostructures are presented. Smooth interfaces of the order of a few monolayers are conﬁrmed and critical thicknesses for coherent growth of the Ga2O3 QW layer are found to be suﬃcient for QWIP applications. info:eu-repo/classification/ddc/530 ddc:530
190	Gyromètre optique basé sur une cavité résonante passive en fibre à cœur creux / Resonant fiber otpical gyroscope based on hollow core fiber Ravaille, Alexia 09 November 2018 (has links) Dans ce manuscrit, nous rapportons les développements, théoriques et expérimentaux, en cours à TRT ainsi qu’à TAV et au LAC, visant la réalisation d’un gyromètre résonant passif en fibre optique à cœur creux atteignant des performances permettant la navigation inertielle. Nous y décrivons mathématiquement l’effet Sagnac, effet relativiste à la base des mesures optiques dans les gyromètres. Ensuite, nous exposons en détail les méthodes utilisées à ce jour pour mesurer des rotations avec des gyromètres passifs par les différentes équipes de recherches. Nous explicitons les limitations de ces méthodes, et en quoi la fibre optique à cœur creux semble être la solution la plus prometteuse pour pallier les défauts des gyromètres passifs résonants actuels. Une partie de cette thèse est alors consacrée à l’étude des propriétés physiques des fibres à cœur creux (Kagomé et bande interdite photonique), telles que leur atténuation, leur capacité à maintenir la polarisation, et leur rétrodiffusion. Nous présentons la première mesure de zone aveugle (plage de faibles vitesses de rotations non mesurables par un gyromètre) dans un gyromètre résonant passif en fibre à cœur creux. Un modèle mathématique est posé pour expliquer le lien entre cette zone aveugle et la rétrodiffusion au sein de la cavité résonante. Nous décrivons ensuite un protocole expérimental permettant de s’affranchir de cette limitation dans notre gyromètre. Nous détaillons enfin la mise en œuvre de ce protocole et caractérisons les performances ainsi atteintes par notre gyromètre / In this manuscript, we report the theoretical and experimental developments at TRT, TAV and LAC, aiming the realization of a hollow-core passive resonant fiber optical gyroscope that can achieve navigation grade performances. We mathematically describe the Sagnac effect, which is a relativistic effect used to optically probe mechanical rotations. Then, we detail the state of the art in passive resonant fiber optical gyroscope development. We identify their limitations, and explain why the hollow core fiber seems to be the best solution to cope with the actual limitations of such gyroscopes. We then focus on two different types of hollow core fibers: Kagome and photonic bandgap. We evaluate their performances in terms of transmission, polarization holding and backscattering. We describe the first measurement of a lock in region in a hollow core fiber passive optical gyroscope, i.e the range of rotation rates that cannot be measured because of backscattering. A mathematical model is propounded to link the lock in to the backscattering of the cavity. We then discuss the experimental protocol that we implemented to circumvent this limitation. Finally, we characterize the performances of our gyroscope based on these features Gyromètre résonant Fibre optique à cœur creux Bande interdite photonique Kagomé Sagnac Resonant gyrometer Hollow core optic fiber Photonic Bandgap fiber Kagome Sagnac

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