Global ETD Search

121	5-6 GHz RFIC Front-End Components in Silicon Germanium HBT Technology Johnson, Daniel Austin 10 May 2001 (has links) In 1997 the Federal Communications Commission (FCC) released 300 MHz of spectrum between 5-6 GHz designated the unlicensed national information infrastructure (U-NII) band. The intention of the FCC was to provide an unlicensed band of frequencies that would enable high-speed wireless local area networks (WLANs) and facilitate wireless access to the national information infrastructure with a minimum interference to other devices. Currently, there is a lack of cost-effective technologies for developing U-NII band components. With the commercial market placing emphasis on low cost, low power, and highly integrated implementations of RF circuitry, alternatives to the large and expensive distributed element components historically used at these frequencies are needed. Silicon Germanium (SiGe) BiCMOS technology represents one possible solution to this problem. The SiGe BiCMOS process has the potential for low cost since it leverages mature Si process technologies and can use existing Si fabrication infrastructure. In addition, SiGe BiCMOS processes offer excellent high frequency performance through the use of SiGe heterojunction bipolar transistors (HBTs), while coexisting Si CMOS offers compatibility with digital circuitry for high level 'system-on-a-chip' integration. The work presented in this thesis focuses on the development of a SiGe RFIC front-end for operation in the U-NII bands. Specifically, three variants of a packaged low noise amplifier (LNA) and a packaged active x2 sub-harmonic mixer (SHM) have been designed, simulated and measured. The fabrication of the Rifts was through the IBM SiGe foundry; the packaging was performed by RF Micro devices. The mixer and LNA designs were fabricated on separate die, packaged individually, and on-chip matched to a 50 ohm system so they could be fully characterized. Measurements were facilitated in a coaxial system using standard FR4 printed circuit boards. The LNA designs use a single stage, cascoded topology. The input ports are impedance matched using inductive emitter degeneration through bondwires to ground. One version of the LNA uses an shunt inductor/series capacitor output match while the other two variation use a series inductor output match. Gain, isolation, match, linearity and noise figure (NF) were used to characterize the performance of the LNAs in the 5 - 6 GHz frequency band. The best LNA design has a maximum gain of 9 dB, an input VSWR between 1.6:1 and 2:1, an output match between 1.7:1 and 3.6:1, a NF better than 3.9 dB and an input intercept point (IIP3) greater than 5.4 dBm. The LNA operates from a 3.3 V supply voltage and consumes 4 mA of current. The SHM is an active, double-balance mixer that achieves x2 sub-harmonic mixing through two quadrature (I/Q) driven, stacked Gilbert-cell switching stages. Single-ended-to-differential conversion, buffering and I/Q phase separation of the LO signal are integrated on-chip. Measurements were performed to find the optimal operating range for the mixer, and the mixer was characterized under these sets of conditions. It was found that the optimal performance of the mixer occurs at an IF of 250-450 MHz and an LO power of -5 dBm. Under these conditions, the mixer has a measured conversion gain of 9.3 dB, a P_1-dB of -15.7 dBm and an 2LO/RF isolation greater than 35 dB at 5.25 GHz. At 5.775 GHz, the conversion gain is 7.7 dB, the P<sub>1-dB</sub> is -15.0 dBm, and the isolation is greater than 35 dB. The mixer core consumes 9.5 mA from a 5.0 V supply voltage. This work is sponsored by RF Microdevices (RFMD)through the CWT affiliate program.The author was supported under a Bradley Foundation fellowship. / Master of Science Front-end Mixer 5 GHz Integrated circuit LNA ISM SiGe RFIC U-NII Sub-harmonic
122	A 60 Ghz Mmic 4x Subharmonic Mixer Chapman, Michael Wayne 14 November 2000 (has links) In this modern age of information, the demands on data transmission networks for greater capacity, and mobile accessibility are increasing drastically. The increasing demand for mobile access is evidenced by the proliferation of wireless systems such as mobile phone networks and wireless local area networks (WLANs). The frequency range over which an oxygen resonance occurs in the atmosphere (~58-62 GHz) has received recent attention as a possible candidate for secure high-speed wireless data networks with a potentially high degree of frequency reuse. A significant challenge in implementing data networks at 60 GHz is the manufacture of low-cost RF transceivers capable of satisfying the system requirements. In order to produce transceivers that meet the additional demands of high-volume, mobility, and compactness, monolithic millimeter wave integrated circuits (MMICs) offer the most practical solution. In the design of radio tranceivers with a high degree of integration, the receiver front-end is typically the most critical component to overall system performance. High-performance low-noise amplifiers (LNAs) are now realizable at frequencies in excess of 100 GHz, and a wide variety of mixer topologies are available that are capable of downconversion from 60 GHz. However, local oscillators (LOs) capable of providing adequate output power at mm-wave frequencies remain bulky and expensive. There are several techniques that allow the use of a lower frequency microwave LO to achieve the same RF downconversion. One of these is to employ a subharmonic mixer. In this case, a lower frequency LO is applied and the RF mixes with a harmonic multiple of the LO signal to produce the desired intermediate frequency (IF). The work presented in this thesis will focus on the development of a GaAs MMIC 4-X subharmonic mixer in Finite Ground Coplanar (FGC) technology for operation at 60 GHz. The mixer topology is based on an antiparallel Schottky diode pair. A discussion of the mechanisms behind the operation of this circuit and the methods of practical implementation is presented. The FGC transmission lines and passive tuning structures used in mixer implementation are characterized with full-wave electromagnetic simulation software and 2-port vector network analyzer measurements. A characterization of mixer performance is obtained through simulations and measurement. The viability of this circuit as an alternative to other high-frequency downconversion schemes is discussed. The performance of the actual fabricated MMIC is presented and compared to currently available 60 GHz mixers. One particular MMIC design exhibits an 11.3 dB conversion loss at an RF of 58.5 GHz, an LO frequency of 14.0 GHz, and an IF of 2.5 GHz. This represents excellent performance for a 4X Schottky diode mixer at these frequencies. Finally, recommendations toward future research directions in this area are made. / Master of Science integrated circuit mixer 60 GHz V-band finite ground coplanar waveguide mm-wave subharmonically pumped subharmonic
123	Translating solid state organic synthesis from a mixer mill to a continuous twin screw extruder Cao, Q., Howard, J.L., Crawford, Deborah E., James, S.L., Browne, D.L. 13 February 2020 (has links) Yes / A study on the translation of a solid-state synthetic reaction from a mechanochemical mixer-mill to a continuous twin-screw extruder is discussed herein. The study highlights some considerations to be made and parameters to be tested in the context of a model fluorination reaction, which is the first organic fluorination to be attempted using extrusion. Upon optimization, which features the first use of grinding auxiliary solids to enable effective synthetic extrusion, the difluorination reaction was successfully translated to the extruder, leading to a 100-fold improvement in Space Time Yield (STY); 29 kg m−3 day−1 in a mixer mill to 3395 kg m−3 day−1 in a twin screw extruder. / D. L. B is grateful to the EPSRC for a First Grant (D. L. B. EP/P002951/1), CRD for a studentship award to J. L. H., Queen’s University Belfast for a Visiting Research Fellowship and the School of Chemistry at Cardiff University for generous support. S. L. J. is grateful to EPSRC for support (EP/L019655/1). Solid-state synthetic reactions Mechanochemical mixer-mill Continuous twin-screw extruder Organic fluorination
124	A highly linear and low flicker-noise CMOS direct conversion receiver front-end for multiband applications Park, Jinsung 09 July 2007 (has links) This dissertation focuses on design and implementation of a highly linear and low flicker-noise receiver front-end based on the direct conversion architecture for multiband applications in a CMOS technology. The dissertation consists of two parts: One, implementation of a highly linear RF receiver front-end and, two, implementation of a low flicker-noise RF receiver front-end based for direct conversion architecture. For multiband applications, key active components, highly linear LNAs and mixers, in the RF front-end receiver have been implemented in a 0.18um CMOS process. Theoretical approaches are analyzed from the perspective of implementation issues for highly linear receiver system and are also compared with measured results. Highly linear LNAs and mixers have been analyzed in terms of noise, linearity and power consumption, etc. For a low flicker-noise receiver front-end based on direct conversion architecture, the design of differential LNA and various low flicker-noise mixers are investigated in a standard 0.18um CMOS process. A differential LNA which shows high linearity was fabricated with a low flicker-noise mixer. Three low flicker-noise mixers were designed, measured and compared to the-state-of-the-arts published by other research institutes and companies. CMOS receiver Mixer LNA Direct conversion low flicker niose RF receiver Highly linear mixer Direct conversion receiver front-end Wireless communication systems Electric current converters
125	Nano-mélangeurs bolométriques supraconducteurs à électrons chauds en Y-Ba-Cu-O pour récepteur térahertz en mode passif / Superconducting Y-Ba-Cu-O hot electron bolometric nano-mixers for terahertz passive receivers Ladret, Romain 06 July 2016 (has links) Nous étudions un mélangeur d'ondes térahertz (THz) réalisé avec le supraconducteur à haute température critique YBaCuO en couches ultraminces (10 à 50 nm). Le travail vise à concevoir un démonstrateur portable pour la détection hétérodyne térahertz passive, avec une cryogénie simplifiée à 60-80 kelvin (projet ANR MASTHER).Le principe de détection est le bolomètre à électrons chauds (HEB) jusqu'à présent développé avec des supraconducteurs à basse température critique. L'effet HEB est mis en ¿uvre dans une constriction en YBaCuO (quelques centaines de nm de dimensions latérales). Cette structure conduit à un détecteur THz sensible et rapide (bande passante instantanée de 100 GHz). Le rayonnement THz est couplé à la constriction par une antenne planaire large bande.En premier lieu, les échanges thermiques entre réservoirs d'électrons et de phonons (YBaCuO et son substrat) sont modélisés. Nous établissons ainsi les conditions optimales pour le HEB en termes de dimensions de la constriction et de puissance de l'oscillateur local requises pour un mélange performant (gain et bruit). Par rapport aux modèles antérieurs, nous introduisons une approche de "point chaud" nouvelle incluant l'influence de la fréquence THz dans YBaCuO, ainsi que l'adaptation d'impédance entre la constriction et l'antenne. En second lieu, nous décrivons l'optimisation des étapes de micro-fabrication des HEB, en particulier les lithographies électronique et optique, pour obtenir des constrictions de 300 nm de côté. De premiers dispositifs ont été testés en détection directe infrarouge. Les performances entre des couches d'YBaCuO ultraminces préparées suivant différentes techniques sont comparées. / We report on the development of a terahertz (THz) wave mixer made from high critical temperature superconducting YBaCuO ultrathin films (10 to 50 nm). The work is part of the MASTHER ANR project aiming at a portable demonstrator for passive terahertz heterodyne detection, implementing simplified cryogenics (60 to 80 kelvin). The detection principle is that of the hot electron bolometer (HEB) so far mainly developed with low critical temperature superconductors. The HEB effect is implemented in an YBaCuO constriction (a few hundred nm in lateral dimensions). This structure can lead to a sensitive and fast THz detector (theoretical instantaneous bandwidth of 100 GHz). The THz radiation is coupled to the YBaCuO constriction by means of a wideband planar antenna. The new aspects first concern the modeling of heat exchange between electrons and phonons reservoirs (YBaCuO and its substrate). Our results establish the optimum operating conditions in terms of dimensions of the constriction and the local oscillator power required for high performance THz mixing (conversion gain and noise temperature). We are introducing in particular a new "hot spot" modeling approach, which takes into account the influence of the terahertz frequency in the YBaCuO material and the impedance matching between the antenna and the constriction. Second, we have developed and optimized the HEB micro-fabrication process in clean room, especially the electronic and optical lithography steps, to obtain constrictions of 300 nm lateral size. Our first devices have been tested by direct detection in the infrared. The performance between YBaCuO ultrathin films prepared using various techniques are compared. YBaCuO Mélangeur hétérodyne Térahertz Couche ultramince supraconductrice Hot electron bolometric terahertz mixer Terahertz wave mixer 537
126	Intelligent real-time environment and process adaptive radio frequency front-ends for ultra low power applications Banerjee, Debashis 21 September 2015 (has links) In the thesis the design of process tolerant, use-aware radio-frequency front-ends were explored. First, the design of fuzzy logic and equation based controllers, which can adapt to multi-dimensional channel conditions, are proposed. Secondly, the thesis proves that adaptive systems can have multiple modes of operation depending upon the throughput requirements of the system. Two such modes were demonstrated: one optimizing the energy-per-bit (energy priority mode) and another achieving the lowest power consumption at the highest throughput (data priority mode). Finally, to achieve process tolerant channel adaptive operation a self-learning methodology is proposed which learns the optimal re-configuration setting for the system on-the-fly. Implications of the research are discussed and future avenues of further research are proposed. Radio frequency Adaptation Low noise amplifier LNA Front-end Fuzzy logic Learning Energy-per-bit Mixer Clustering Process Variation Channel
127	Detect, Bite, Slam Miharbi, Ali 01 January 2010 (has links) This paper explores the influences, ideas and motivations behind my MFA thesis exhibition. It primarily focuses on how I developed my work for the show in connection to my previous work as well as work created by other artists who explored the impacts of new media in the last decade. With the advancement of social media, digital technologies no longer have their infamous coldness. Our perceptions and the metaphors in language are all reflected onto the machines we create while in return they also shape and redefine our lives. It becomes increasingly difficult to talk about dialectics such as machine-human, virtual-real, and nature-culture. With the aid of some humor, I attempted to reflect on the marriage of these old oppositions and this paper will discuss the foundations of these ideas as well as my practice in general. mars face detection misuse bites mixer food torture wheel reality perception language remix data Art and Design Arts and Humanities
128	Projeto de um bloco LNA-misturador para radiofrequência em tecnologia CMOS. / A merged RF-CMOS LNA-mixer design in CMOS technology. Ayala Pabón, Armando 15 December 2009 (has links) Este trabalho apresenta o projeto de um bloco LNA-Misturador dentro de um mesmo circuito integrado para aplicações em um receptor Bluetooth 2;45GHz. Uma estratégia de projeto bem clara, concisa e com uma boa base física e matemática foi desenvolvida para auxiliar o processo de projeto de um bloco LNA-Misturador, composto por um LNA cascode em cascata com um misturador de chaveamento de corrente com entradas simples e degeneração indutiva nas fontes dos estágios de transcondutância. Esta estratégia foi adaptada de trabalhos apresentados na literatura. A estratégia de projeto proposta considera o compromisso entre ruído, linearidade, ganho, dissipação de potência, casamento de impedâncias e isolamento de portas, usando as dimensões dos dispositivos e condições de polarização como variáveis de projeto. Com base nesta estratégia se obteve um bloco LNA-Misturador que atinge algumas especificações propostas. Um bloco LNA-Misturador foi projetado e fabricado em uma tecnologia CMOS 0;35µm para validar a estratégia de projeto proposta. Além disso, para atingir os objetivos, durante o desenvolvimento deste trabalho foi dada atenção especial no projeto dos indutores. Foi projetado, fabricado e medido um chip de teste. Para tal fim foram aplicadas técnicas e estruturas de de-embedding nas medidas para conseguir resultados mais confiáveis. Os resultados experimentais obtidos para os indutores e os resultados preliminares do bloco LNA-Misturador s~ao satisfatórios de acordo com as especificações e os esperados das simulações. No entanto, os indutores integrados degradam significativamente o desempenho do bloco LNA-Misturador. Se forem usados processos de fabricação nos quais os indutores apresentem melhor desempenho, os resultados do bloco LNA-Misturador aplicando a estratégia de projeto desenvolvida neste trabalho podem ser melhorados. Finalmente, é importante ressaltar que a estratégia de projeto proposta neste trabalho já está sendo usada e adaptada em outros projetos com o propósito de melhorar os resultados obtidos, e conseguir auxiliar o processo de projeto deste tipo de blocos. / This work presents a fully integrated LNA-Mixer design for a Bluetooth receiver application at 2:45GHz. A concise design strategy with good physics and mathematics basis was developed to assist the design process of a LNA-Mixer block, formed by a cascode LNA in cascade to a single balanced current commutation Mixer with inductive degeneration. This strategy was adapted from literature and considers the trade-offs between noise, linearity, gain, power dissipation, impedance matching and ports isolation, using the device dimensions and bias conditions as design variables. Based on this strategy, the proposed LNA-Mixer design specifications were achieved. To validate the proposed design strategy, the LNA-Mixer were fabricated in a 0:35µm CMOS process. Furthermore, to achieve the specifications, during the development of this work a special attention to the RF CMOS inductors was given. A test chip was designed, fabricated and measured applying de-embedding structures to obtain more reliable results. The experimental results obtained for the inductors and the preliminary results for the LNA-Mixer are satisfactory compared to the specifications and as expected from simulations. However, the integrated inductors degrade the performance of the block significantly and if a manufacturing process in which the inductor has better performance is used, the resulting LNA-Mixer design applying the strategy developed in this work can be improved. Finally, it is important to highlight that the design strategy proposed in this work is already being used and adapted in other designs in order to improve the results, and to assist the design process of such blocks. Amplificadores Circuitos integrados CMOS low noise amplifiers CMOS mixers De-embedding structures Integrated circuits LNA-Mixer Misturadores de sinal CMOS
129	Dispersion de nanotubes de carbone dans une matrice élastomère EPDM par des méthodes douces de mélanges. Vers le contrôle des propriétés rhéologiques et électriques. / Dispersion of Carbon Nanotubes in an EPDM rubber matrix using soft mixing techniques. Toward the control of rheological and electrical properties. Charman, Maxime 15 December 2011 (has links) Grâce à leurs propriétés mécaniques et électroniques élevées, les NanoTubes de Carbone (NTC) semblent être les nanocharges idéales pour conférer des propriétés optimum à des matériaux composites, en particulier ceux qui sont élaborés à partir de matrices élastomères. Cependant, pour obtenir une amélioration significative des propriétés une bonne dispersion dans la matrice est nécessaire. La dispersion des NTC dans une matrice élastomère de type EPM est explorée ici en employant un copolymère statistique, le poly(éthylène-stat-acétate de vinyle) (EVA), comme agent dispersant. Les outils classiques de mélange des élastomères, mélangeur interne et mélangeur à cylindres, qui sont des techniques de mélange douces, ont été utilisés dans le cadre de cette étude. Nous avons montré qu’à faible taux de NTC dans la matrice leur dispersion était contrôlée par deux paramètres clés (i) la viscosité de la matrice EPM et (ii) la concentration en EVA. L’augmentation des concentrations de NTC a permis de mettre en évidence que les propriétés rhéologiques et électriques des nanocomposites variaient brusquement à partir de concentrations critiques (seuil de percolation) assez faibles permettant de justifier l’utilisation du système EPM-EVA sélectionné. Nous avons alors préparé un mélange maître EPM-EVA chargé à 20% en NTC possédant de très bonnes propriétés de conductivité. Des mélanges à base d’EPDM chargés par des nanotubes de carbone, du noir de carbone ou le mélange des deux ont également été analysés. Nous avons démontré que la dilution d’un mélange maître permet d’obtenir un élastomère chargé en NTC avec une viscosité Mooney constante et avec un impact fort sur la cinétique de vulcanisation de l’élastomère (accélération de la réaction). Un effet de synergie entre noir de carbone et NTC a été mis en évidence au niveau des propriétés mécaniques mais pas pour les propriétés électriques. / The outstanding properties of Carbon NanoTubes (CNTs) make them ideal candidates for use in nanocomposites, and particularly in those based on rubber matrix. However, to obtain an improvement of the properties, a good degree of dispersion of the CNT in the matrix is crucial. The CNT dispersion in an EPM rubber is investigated here by using a statistical copolymer, the ethylene-stat-vinyl acetate (EVA), as dispersing agent. In this study, we work with the classic methods used for rubber mixing, like an internal mixer and an open two roll mill, which are soft mixing techniques. At low CNT rate in the matrix, the dispersion is controlled by two parameters such as the EPM matrix viscosity and the EVA concentration. The rheological and electrical properties varied abruptly when the CNT concentration is increased in the matrix. The low values obtained for this percolation threshold justify the use of EPM-EVA system. We have prepared an EPM-EVA master batch loaded with 20% of CNT and possessing very good conductive properties. We studied EPDM compound filled with carbon nanotubes, carbon black or the blend of both. We have demonstrated that the dilution of the master batch allows us to obtain a rubber filled with a constant Mooney viscosity but with an important impact on the vulcanization kinetics of elastomers. The synergistic effect between carbon black and carbon nanotubes has been shown on the mechanicals properties but not on the electrical ones. Nanotube de carbone Elastomère Dispersion Rhéologie Conductivité Electrique Mélangeur interne Banbury Carbon nanotube Elastomer Dispersion Rheology Electrical conductivity Banbury mixer
130	A Microfluidic Platform to Enable Screening of Immobilised Biomolecule Mixtures Michael Hines Unknown Date (has links) Abstract This thesis describes the design, fabrication and operation of a microfluidic device for the screening of biomolecule mixture surface mediated effects. The characterisation of a surface immobilisation strategy that will allow the robust attachment of candidate biomolecules on a substrate for use in cell culture applications. This is carried out in the form of a modified and optimised layer-by-layer surface immobilisation strategy and its subsequent thorough and robust characterisation. This was achieved by compiling and critically analysing large amounts of quartz crystal microbalance with dissipation (QCM-D) data and the model utilised to provide meaningful, physical data as an output. QCM-D data was combined with surface plasmon resonance (SPR) data to validate the assumptions used within the QCM-D model package. Further evidence demonstrating the presence of the multilayer, as described by QCM-D and SPR, is achieved using x-ray photoelectron spectroscopy (XPS). These results show that the multilayer surface is robustly attached to the substrate and consists of a large amount of water whilst being able to immobilise mixtures of four proteins. A custom protocol for fabricating these two layer devices was devised and is presented. Scale limitations have been overcome to provide mixing capabilities for large extracellular matrix molecules to be immobilised on the previously described, microfluidically generated surface immobilisation strategy. The optimisation and characterisation of the mixing within this microfluidic device, affected by the incorporated staggered herring bone mixer is also shown. Using dynamic force spectroscopy (DFS) along with a custom designed force curve data processing and analysis package, the spatial localisation of a mixture of four immobilised biomolecules was determined. The aim of this study was to compare the spatial localization of a mixture of four biomolecules created by; standard cell culture protocols (adsorbed from bulk onto tissue culture polystyrene) and a surface created via microfluidic deposition on top of a previously described surface immobilisation strategy. The design and robust application of this custom analysis package allows the definition of a “Barricade of Specificity” such that interactions between an antibody functionalised AFM tip and a surface composed of a mixture of proteins, to be categorised as either a “true” specific interaction, or a non-specific interaction. The application of this Barricade of Specificity thus allows the spatial localisation of four immobilized biomolecules to be determined with a large degree of accuracy as a result of the large rage of non-specific interactions surveyed and the strict definition of a valid rupture force. The final chapter details the application of the microfluidic platform to enable high throughput screening of the effects of extracellular matrix (ECM) molecules, singly and in combination, with regards to the effect on the expression of cell surface markers on umbilical cord blood (UCB) derived CD34+ cells. Careful selection of candidate ECM molecules, cytokine and oxygen concentration has resulted in little difference in the effect on UCB derived CD34+ cells differentiation state after seven days in culture. The major effect has been the maturation towards lymphocyte and leukocyte precursors. However, of the four ECM molecules tested individually, in binary and in quaternary combinations, osteopontin (Opn) and laminin (Ln) demonstrated differences compared to other surfaces tested. In order to further assess the effect of these protein surfaces on the cell surface marker expression of UCB derived CD34+ cells, further tests are warranted for increased periods of time to enable greater discrimination in marker expression and thus increase our understanding of the fundamental biology of this rare and clinically useful cell source. hematopoietic stem cells multilayer photolithography microfluidic mixing staggered herringbone mixer dynamic force spectroscopy

Search results