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A High Temperature Wideband Low Noise AmplifierCunningham, Michael Lawrence 27 January 2016 (has links)
As the oil industry continues to drill deeper to reach new wells, electronics are being required to operate at extreme pressures and temperatures. Coupled with substantial real-time data targets, the need for robust high speed electronics is quickly on the rise. This paper presents a high temperature wideband low noise amplifier (LNA) with zero temperature coefficient maximum available gain (ZTCMAG) biasing for a downhole communication system. The proposed LNA is designed and prototyped using 0.25μm GaN on SiC RF transistor technology, which is chosen due to the high junction temperature capability. Measurements show that the proposed LNA can operate reliably up to an ambient temperature of 230°C with a minimum noise figure (NF) of 2.0 dB, gain of 16.1 dB, and P1dB of 19.1 dBm from 230.5MHz — 285.5MHz. The maximum variation with temperature from 25°C to 230°C is 1.53dB for NF and 0.65dB for gain. / Master of Science
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System Design of a High-Temperature Downhole TransceiverKerrigan, Brannon Michael 12 September 2018 (has links)
The oil and gas industry, aerospace, and automotive industries are constantly pushing technology beyond their current operational boundaries, spurring the need for extreme environment electronics. The oil and gas industry, in particular, is the oldest and largest market for high-temperature electronics, where the operating environment can extend up to 260 degrees Celsius. The electronics currently employed in this field are only rated to 200 degrees Celsius, but with the rise of wideband gap technologies, this could be extended to 250 degrees Celsius or more without the needed for active or passive cooling. This reduces the complexity, weight, and cost of the system while improving reliability. In addition, current downhole telemetry data rates are insufficient for supporting more sophisticated and higher resolution well-logging sensors. Increasing the data rates can also save the industry significant amount of time by decreasing the amount of well-logging excersions and by increasing the logging speed.
Previous work done by this research group saw the prototyping of a high bit rate transceiver operating at 230 MHz - 300 MHz and 230 degrees Celsius; however, at these frequencies, the system could not meet size requirements. Thus, a new high-temperature high data rate transceiver design using the 2.4 GHz - 2.5 GHz ISM band is proposed to miniaturize the design and to allow for IC implementation. The transceiver was designed to meet the minimum specifications necessary to give designers flexibility between power consumption and performance. The performance of the design is simulated using AWR design environment software, which shows the system can support a downlink data rate up to 68 Mbps and an uplink data rate up to 170 Mbps across 10 channels. The effects temperature has on the system performance is also evaluated in the simulation. / Master of Science / The oil and gas industry is currently the largest and oldest market for high-temperature electronics. One of the major applications within this industry for high-temperature electronics is known as well-logging, during which a suite of sensors and systems is lowered into a well to survey the health and geology of the well. Among these sensors and systems, the communication system is one of the most crucial components as it relays real-time data back to the surface during the well-logging operation. Current high-temperature communication systems are capable of operating up to 200 ℃, meeting the operating requirements of current wells. As these wells deplete, however, new wells must be explored, and higher operating temperatures are expected. In addition, the communication systems currently employed fail to meet increasing data rate demands due to the growing complexity of the sensors.
Recent developments in semiconductor technologies have given rise to devices, which can increase the operating temperature of electronics up to 250 ℃ while meeting demands for high data rate communication systems. Previous work has leveraged these devices to prototype such a system; however, the proof-of-concept failed to meet size and weight restrictions of practical systems. Therefore, a new system design for a high-temperature high data rate communication system is proposed. The system operates at 2.4 – 2.5 GHz to miniaturize the circuits and make chip implementation possible. The impacts of temperature on the system are investigated and the system performance is simulated within its intended operating temperature range. Developments from this research can be extended to the automotive and aerospace industries, where demand for high-temperature electronics is growing.
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Raman spectroscopic identification of scytonemin and its derivatives as key biomarkers in stressed environmentsVarnali, T., Edwards, Howell G.M. 03 November 2014 (has links)
No / Raman spectroscopy has been identified as an important first-pass analytical technique for deployment on planetary surfaces as part of a suite of instrumentation in projected remote space exploration missions to detect extant or extinct extraterrestrial life signatures. Aside from the demonstrable advantages of a non-destructive sampling procedure and an ability to record simultaneously the molecular signatures of biological, geobiological and geological components in admixture in the geological record, the interrogation and subsequent interpretation of spectroscopic data from these experiments will be critically dependent upon the recognition of key biomolecular markers indicative of life existing or having once existed in extreme habitats. A comparison made with the characteristic Raman spectral wavenumbers obtained from standards is not acceptable because of shifts that can occur in the presence of other biomolecules and their host mineral matrices. In this paper, we identify the major sources of difficulty experienced in the interpretation of spectroscopic data centring on a key family of biomarker molecules, namely scytonemin and its derivatives; the parent scytonemin has been characterized spectroscopically in cyanobacterial colonies inhabiting some of the most extreme terrestrial environments and, with the support of theoretical calculations, spectra have been predicted for the characterization of several of its derivatives which could occur in novel extraterrestrial environments. This work will form the foundation for the identification of novel biomarkers and for their Raman spectroscopic discrimination, an essential step in the interpretation of potentially complex and hitherto unknown biological radiation protectants based on the scytoneman and scytonin molecular skeletons which may exist in niche geological scenarios in the surface and subsurface of planets and their satellites in our Solar System.
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Navigating Extremes: Advancing 3D-IC with Flexible Glass for Harsh EnvironmentsJoo Min Kim (18838408) 17 June 2024 (has links)
<p dir="ltr">The rapid evolution of semiconductor technology, driven by the limitations of Moore's Law, necessitates innovative approaches to enhance device performance and miniaturization. This thesis explores the advancement of three-dimensional integrated circuits (3D-ICs) using flexible glass-based substrates, focusing on their application in extreme environments. Flexible glass emerges as a promising material for 3D-IC packaging due to its superior electrical insulation, thermal stability, chemical resistance, and mechanical strength. These properties are critical for maintaining device reliability and functionality under harsh conditions such as high temperatures, humidity, and radiation. Their unique properties make them particularly suited for applications in aerospace, military, and automotive industries, where electronics must endure severe operational environments. The research presented in this thesis provides a comprehensive examination of the processes involved in fabricating flexible glass-based 3D-ICs, detailing methodologies for integrating semiconductor components onto a flexible glass substrate using common platform technology (CPT). This approach ensures compatibility across diverse systems and enhances the scalability and cost-effectiveness of 3D-IC solutions. Experimental results indicate that 3D-ICs incorporating flexible glass substrates exhibit enhanced functionality and durability. This study underscores the transformative potential of flexible glass in revolutionizing the design and performance of future electronic systems, ensuring their operability and longevity in demanding settings. By addressing the challenges of traditional packaging materials, flexible glass represents a significant advancement in 3D-IC technology, promising to broaden the operational landscape of electronic devices and change how they are deployed across various high-stakes fields.</p>
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The design of SiGe integrated circuit components for extreme environment systems and sensorsDiestelhorst, Ryan Matthew 13 January 2014 (has links)
A background investigation of the total-dose radiation tolerance of a third generation complementary SiGe:C BiCMOS technology platform was performed. Tolerance was quantified under proton and X-ray radiation sources for both the npn and pnp HBT, as well as for an operational amplifier built with these devices. Furthermore, a technique known as junction isolation radiation hardening was proposed and tested with the goal of improving the SEE sensitivity of the npn by reducing the charge collected by the subcollector in the event of a direct ion strike.
Three independent systems were designed, including: 1) a charge amplification channel developed as part of a remote electronics unit for the lunar environment, 2) variable bias circuitry for a self-healing radar receiver, and 3) an ultra-fast x-ray detector for picosecond scale time-domain measurements of evolving chemical reactions. The first two projects capitalized on the wide-temperature performance and radiation tolerance of the SiGe HBT, allowing them to operate under extreme environmental conditions reliably and consistently. The third design makes use of the high-frequency capabilities of the HBT, particularly in emitter-coupled logic (ECL) configurations. Findings concerning the performance of these systems and implications for future research are discussed.
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Silicon-germanium BiCMOS and silicon-on-insulator CMOS analog circuits for extreme environment applicationsEngland, Troy Daniel 22 May 2014 (has links)
Extreme environments pose major obstacles for electronics in the form of extremely wide temperature ranges and hazardous radiation. The most common mitigation procedures involve extensive shielding and temperature control or complete displacement from the environment with high costs in weight, power, volume, and performance. There has been a shift away from these solutions and towards distributed, in-environment electronic systems. However, for this methodology to be viable, the requirements of heavy radiation shielding and temperature control have to be lessened or eliminated. This work gained new understanding of the best practices in analog circuit design for extreme environments. Major accomplishments included the over-temperature -180 C to +120 C and radiation validation of the SiGe Remote Electronics Unit, a first of its kind, 16 channel, sensor interface for unshielded operation in the Lunar environment, the design of two wide-temperature (-180 C to +120 C), total-ionizing-dose hardened, wireline transceivers for the Lunar environment, the low-frequency-noise characterization of a second-generation BiCMOS process from 300 K down to 90 K, the explanation of the physical mechanisms behind the single-event transient response of cascode structures in a 45 nm, SOI, radio-frequency, CMOS technology, the analysis of the single-event transient response of differential structures in a 32 nm, SOI, RF, CMOS technology, and the prediction of scaling trends of single-event effects in SOI CMOS technologies.
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Interface circuit designs for extreme environments using SiGe BiCMOS technologyFinn, Steven Ernest 31 March 2008 (has links)
SiGe BiCMOS technology has many advantageous properties that, when leveraged, enable circuit design for extreme environments. This work will focus on designs targeted for space system avioinics platforms under the NASA ETDP program. The program specifications include operation under temperatures ranging from -180 C to +125 C and with radiation tolerance up to total ionizing dose of 100 krad with built-in single-event latch-up tolerance. To the author's knowledge, this work presents the first design and measurement of a wide temperature range enabled, radiation tolerant as built, RS-485 wireline transceiver in SiGe BiCMOS technology. This work also includes design and testing of a charge amplification channel front-end intended to act as the interface between a piezoelectric sensor and an ADC. An additional feature is the design and testing of a 50 Ohm output buffer utilized for testing of components in a lab setting.
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Genetic Algorithm Based Design and Optimization of VLSI ASICs and Reconfigurable HardwareFernando, Pradeep Ruben 17 October 2008 (has links)
Rapid advances in integration technology have tremendously increased the design complexity of very large scale integrated (VLSI) circuits, necessitating robust optimization techniques in many stages of VLSI design. A genetic algorithm (GA) is a stochastic optimization technique that uses principles derived from the evolutionary process in nature. In this work, genetic algorithms are used to alleviate the hardware design process of VLSI application specific integrated circuits (ASICs) and reconfigurable hardware.
VLSI ASIC design suffers from high design complexity and a large number of optimization objectives requiring hierarchical design approaches and multi-objective optimization techniques. The floorplanning stage of the design cycle becomes highly important in hierarchical design methods. In this work, a multi-objective genetic algorithm based floorplanner has been developed with novel crossover operators to address the multi-objective floorplanning problem for VLSI ASICs. The genetic floorplanner achieves significant wirelength savings (>19% on average) with little or no increase in area ( < 3% penalty) over previous floorplanners that perform simultaneous area and wirelength minimization.
Hardware implementation of genetic algorithms is gaining importance because of their proven effectiveness as optimization engines for real-time applications. Earlier hardware implementations suffer from major drawbacks such as absence of GA parameter programmability, rigid pre-defined system architecture, and lack of support for multiple fitness functions. A compact IP core that implements a general purpose GA engine has been designed to realize evolvable hardware in field programmable gate array devices. The designed GA core achieved a speedup of around 5.16x over an analogous software implementation.
Novel reconfigurable analog architectures have been proposed to realize extreme environment analog electronics. In this work, a digital framework has been developed to realize self reconfigurable analog arrays (SRAA) where genetic algorithms are used to evolve the required analog functionality and compensate performance degradation in extreme environments. The framework supports two methods of compensation, namely, model based lookup and genetic algorithm based compensation and is scalable in terms of the number of fitness evaluation modules. The entire framework has been implemented as a digital ASIC in a leading industrystrength silicon-on-insulator (SOI) technology to obtain high performance and a small form factor.
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Caracterização de bactérias halotolerantes isoladas do bioma caatinga e avaliação da produção de biopolímeros. / Characterization of halotolerant bacteria isolated from Caatinga and evaluation of biopolymers production.Pinilla, Maria Paula Parada 06 December 2016 (has links)
Os organismos extremófilos são considerados atualmente reservatórios de novas biomoléculas de interesse biotecnológico. Dentro deste grupo encontram-se os microrganismos que requerem altas concentrações de sal para crescer, denominados halófilos. Também existem os halotolerantes que são aqueles microrganismos que não precisam de sal para proliferar, mas toleram altas concentrações de NaCl. Os ambientes salinos provaram ser uma fonte rica de microrganismos halotolerantes produtores de novos compostos naturais e, portanto, a pesquisa nestes ambientes torna-se de grande importância. No Brasil, na região salina de Areia Branca no bioma caatinga, foram isoladas bactérias halotolerantes que foram estudadas com o objetivo de avaliar a produção de novos biopolímeros de interesse biotecnológico. Acredita-se que os polímeros naturais desses microrganismos extremos podem ter aplicações inovadoras ou características diferentes às tradicionais. Neste estudo, os isolados foram identificados em nível de gênero com base na análise da sequência do gene 16s rRNA. Os isolados foram principalmente bactérias Gram-positivas atribuídas às famílias Bacillaceae, Staphylococcaceae, Microbacteriaceae e uma bactéria Incertae Sedis do filo firmicutes, afiliadas aos gêneros Bacillus, Staphylococcus, Curtobacterium e Exiguobacterium, respectivamente. Apenas um isolado Gram-negativo foi identificado e atribuído como membro da família Pseudomonadaceae, incluso no gênero Pseudomonas. Avaliou-se a tolerância ao sal dos isolados em meio TSB suplementado com 5, 35, 60 e 120 g/L de NaCl. Todos os isolados apresentaram a capacidade de crescer nas quatro concentrações de NaCl avaliadas, com exceção do isolado Exiguobacterium sp. sac36 que não cresceu na concentração de 120 g/L de NaCl no meio. Realizaram-se ensaios de acúmulo de polihidroxialcanoatos (PHA) e evidenciou-se que quatro isolados do gênero Bacillus são capazes de acumular 3-hidroxibutirato (3HB) a partir de glicose, xilose, e alguns destes em glicerol. Adicionalmente, confirmou-se que quando há altas concentrações de NaCl no meio, o acúmulo de 3HB dos isolados produtores diminui. Observou-se também que doze isolados halotolerantes são produtores de exopolissacarídeos (EPS). Testes realizados indicaram que os mesmos podem ter efeitos imunoestimulantes em macrófagos. Finalmente, avaliou-se a produção de ácido hialurônico (AH) pelos isolados halotolerantes. Segundo sugere o método de Alcian blue, todos os isolados foram capazes de produzir AH, mostrando que a maior parte deles acumulou o biopolímero em concentrações maiores ou semelhantes ao controle. Os resultados obtidos evidenciam que os isolados halotolerantes avaliados são uma fonte rica em compostos com atividades promissoras para as diferentes indústrias. O presente trabalho contribui no estudo do potencial biotecnológico de microrganismos isolados no bioma caatinga, destacando sua biodiversidade, versatilidade e a necessidade de continuar explorando esses ambientes extremos pouco estudados. / Extremophile organisms are considered reservoirs of new biomolecules of biotechnological interest. In this group there are microorganisms that require high salt concentration to grow, called halophiles, and halotolerant microorganisms, that do not need salt to proliferate but can tolerate high concentrations of NaCl. Saline environments proved to be a rich source of new natural compounds by halotolerant producers and therefore, research in these environments becomes of great importance. In Brazil, in the saline region of Areia Branca in the caatinga biome, halotolerant bacteria were isolated and studied in order to evaluate the production of new biopolymers of biotechnological interest. It is believed that the natural polymers of those extreme microorganisms could have innovative applications or different characteristics from the traditional biopolymers. In this study, the isolates were identified at the genus level based on 16S rRNA gene sequence analysis. Isolates were mainly Gram-positive bacteria from Bacillaceae, Staphylococcaceae and Microbacteriaceae families, and Bacillus, Exiguobacterium, Staphylococcus and Curtobacterium genera. One of the Gram-negative isolate was identified as member of the Pseudomonadaceae family, genus Pseudomonas. The evaluation of salt tolerance of the bacterial isolates on TSB medium supplemented with 5, 35, 60 and 120 g / L NaCl was performed. All the isolates showed the ability to grow in the four concentrations evaluated, except for Exiguobacterium sp. sac36, that did not grow at 120 g / L NaCl. Polyhydroxyalkanoate (PHA) accumulation assays were performed using glucose, xylose and glycerol as carbon source. The results showed that four strains of the genus Bacillus were able to accumulate 3-hydroxybutyrate (3HB) in all conditions. Additionally, it was confirmed that the presence of high concentrations of NaCl in the medium causes a decrease in 3HB accumulation in the cells. It was observed that twelve halotolerant bacteria produced exopolysaccharides (EPS). Tests performed indicated that those EPS could have immunostimulatory effects on macrophages. Finally, hyaluronic acid (HA) production was evaluated. According to Alcian blue method, all strains were able to produce HA, showing that most of the isolates accumulated the biopolymer in higher or similar concentrations to the control. The results showed that the halotolerant isolates are a rich source of compounds with promising activities for different industries. This study contributes to the knowledge of microorganisms from the caatinga biome and their biotechnological potential, highlighting their biodiversity, versatility and the need to continue exploring these poorly studied extreme environments.
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SiGe HBTs Operating at Deep Cryogenic temperaturesYuan, Jiahui 09 April 2007 (has links)
As Si-manufacturing compatible SiGe HBTs are making rapid in-roads into RF through mm-wave circuit applications, with performance levels steadily marching upward, the use of these devices under extreme environment conditions are being studied extensively. In this work, test structures of SiGe HBTs were designed and put into extremely low temperatures, and a new negative differential resistance effect and a novel collector current kink effect are investigated in the cryogenically-operated SiGe HBTs.
Theory based on an enhanced positive feedback mechanism associated with heterojunction barrier effect at deep cryogenic temperatures is proposed. The accumulated charge induced by the barrier effect acts at low temperatures to enhance the total collector current, indirectly producing both phenomena. This theory is confirmed using calibrated 2-D DESSIS simulations over temperature. These unique cryogenic effects also have significant impact on the ac performance of SiGe HBTs operating at high-injection. Technology evolution plays an important role in determining the magnitude of the observed phenomena, and the scaling implications are addressed. Circuit implication is discussed.
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