Global ETD Search

1	STUDY OF SINGLE-EVENT EFFECTS ON DIGITAL SYSTEMS 2015 August 1900 (has links) Microelectronic devices and systems have been extensively utilized in a variety of radiation environments, ranging from the low-earth orbit to the ground level. A high-energy particle from such an environment may cause voltage/current transients, thereby inducing Single Event Effect (SEE) errors in an Integrated Circuit (IC). Ever since the first SEE error was reported in 1975, this community has made tremendous progress in investigating the mechanisms of SEE and exploring radiation tolerant techniques. However, as the IC technology advances, the existing hardening techniques have been rendered less effective because of the reduced spacing and charge sharing between devices. The Semiconductor Industry Association (SIA) roadmap has identified radiation-induced soft errors as the major threat to the reliable operation of electronic systems in the future. In digital systems, hardening techniques of their core components, such as latches, logic, and clock network, need to be addressed. Two single event tolerant latch designs taking advantage of feedback transistors are presented and evaluated in both single event resilience and overhead. These feedback transistors are turned OFF in the hold mode, thereby yielding a very large resistance. This, in turn, results in a larger feedback delay and higher single event tolerance. On the other hand, these extra transistors are turned ON when the cell is in the write mode. As a result, no significant write delay is introduced. Both designs demonstrate higher upset threshold and lower cross-section when compared to the reference cells. Dynamic logic circuits have intrinsic single event issues in each stage of the operations. The worst case occurs when the output is evaluated logic high, where the pull-up networks are turned OFF. In this case, the circuit fails to recover the output by pulling the output up to the supply rail. A capacitor added to the feedback path increases the node capacitance of the output and the feedback delay, thereby increasing the single event critical charge. Another differential structure that has two differential inputs and outputs eliminates single event upset issues at the expense of an increased number of transistors. Clock networks in advanced technology nodes may cause significant errors in an IC as the devices are more sensitive to single event strikes. Clock mesh is a widely used clocking scheme in a digital system. It was fabricated in a 28nm technology and evaluated through the use of heavy ions and laser irradiation experiments. Superior resistance to radiation strikes was demonstrated during these tests. In addition to mitigating single event issues by using hardened designs, built-in current sensors can be used to detect single event induced currents in the n-well and, if implemented, subsequently execute fault correction actions. These sensors were simulated and fabricated in a 28nm CMOS process. Simulation, as well as, experimental results, substantiates the validity of this sensor design. This manifests itself as an alternative to existing hardening techniques. In conclusion, this work investigates single event effects in digital systems, especially those in deep-submicron or advanced technology nodes. New hardened latch, dynamic logic, clock, and current sensor designs have been presented and evaluated. Through the use of these designs, the single event tolerance of a digital system can be achieved at the expense of varying overhead in terms of area, power, and delay. Single event effects Charge sharing nano technology flip-flop Radiation Hardening By Design
2	Radiation Induced Effects in Electronic Devices and Radiation Hardening By Design Techniques Walldén, Johan January 2014 (has links) The aim with this thesis has been to make a survey of radiation hardened electronics, explaining why and how radiation affects electronics and what can be done to harden it. The effects radiation have on electronics in general and in specific commonly used devices are explained qualitatively. The effects are divided into Displacement Damage (DD), Total Ionizing Dose (TID) and Single Event Effects (SEEs). The devices explained are MOSFETs, Silicon On Insulator (SOI) transistors, 3D-transistors, Power transistors, Optocouplers, Field Programmable Gate Arrays (FPGAs), three dimensional circuits (3D-ICs) and Flash memories. Different radiation hardening by design (RHBD) techniques used to reduce or to remove the negative effects radiation induces in electronics are also explained. The techniques are Annular transistors, Enclosed source/drain transistors, Guard rings, Triple Modular Redundancy (TMR), Dual Interlocked Storage Cells (DICE), Guard gates, Temporal filtering,Multiple drive, Charge dissipation, Differential Charge Cancellation (DCC), Scrubbing, Lockstep, EDAC codes and Watchdog timers. Radiation Radiation Hardening By Design RHBD Displacement Damage DDD Total Ionizing
3	Total Dose Effects and Hardening-by-Design Methodologies for Implantable Medical Devices January 2010 (has links) abstract: Implantable medical device technology is commonly used by doctors for disease management, aiding to improve patient quality of life. However, it is possible for these devices to be exposed to ionizing radiation during various medical therapeutic and diagnostic activities while implanted. This commands that these devices remain fully operational during, and long after, radiation exposure. Many implantable medical devices employ standard commercial complementary metal-oxide-semiconductor (CMOS) processes for integrated circuit (IC) development, which have been shown to degrade with radiation exposure. This necessitates that device manufacturers study the effects of ionizing radiation on their products, and work to mitigate those effects to maintain a high standard of reliability. Mitigation can be completed through targeted radiation hardening by design (RHBD) techniques as not to infringe on the device operational specifications. This thesis details a complete radiation analysis methodology that can be implemented to examine the effects of ionizing radiation on an IC as part of RHBD efforts. The methodology is put into practice to determine the failure mechanism in a charge pump circuit, common in many of today's implantable pacemaker designs, as a case study. Charge pump irradiation data shows a reduction of circuit output voltage with applied dose. Through testing of individual test devices, the response is identified as parasitic inter-device leakage caused by trapped oxide charge buildup in the isolation oxides. A library of compact models is generated to represent isolation oxide parasitics based on test structure data along with 2-Dimensional structure simulation results. The original charge pump schematic is then back-annotated with transistors representative of the parasitic. Inclusion of the parasitic devices in schematic allows for simulation of the entire circuit, accounting for possible parasitic devices activated by radiation exposure. By selecting a compact model for the parasitics generated at a specific dose, the compete circuit response is then simulated at the defined dose. The reduction of circuit output voltage with dose is then re-created in a radiation-enabled simulation validating the analysis methodology. / Dissertation/Thesis / M.S. Electrical Engineering 2010 Electrical Engineering charge pump oxide-trapped charge Radiation Effects radiation hardening by design Total Ionizing Dose
4	Methodical Design Approaches to Multiple Node Collection Robustness for Flip-Flop Soft Error MItigation January 2015 (has links) abstract: The space environment comprises cosmic ray particles, heavy ions and high energy electrons and protons. Microelectronic circuits used in space applications such as satellites and space stations are prone to upsets induced by these particles. With transistor dimensions shrinking due to continued scaling, terrestrial integrated circuits are also increasingly susceptible to radiation upsets. Hence radiation hardening is a requirement for microelectronic circuits used in both space and terrestrial applications. This work begins by exploring the different radiation hardened flip-flops that have been proposed in the literature and classifies them based on the different hardening techniques. A reduced power delay element for the temporal hardening of sequential digital circuits is presented. The delay element single event transient tolerance is demonstrated by simulations using it in a radiation hardened by design master slave flip-flop (FF). Using the proposed delay element saves up to 25% total FF power at 50% activity factor. The delay element is used in the implementation of an 8-bit, 8051 designed in the TSMC 130 nm bulk CMOS. A single impinging ionizing radiation particle is increasingly likely to upset multiple circuit nodes and produce logic transients that contribute to the soft error rate in most modern scaled process technologies. The design of flip-flops is made more difficult with increasing multi-node charge collection, which requires that charge storage and other sensitive nodes be separated so that one impinging radiation particle does not affect redundant nodes simultaneously. We describe a correct-by-construction design methodology to determine a-priori which hardened FF nodes must be separated, as well as a general interleaving scheme to achieve this separation. We apply the methodology to radiation hardened flip-flops and demonstrate optimal circuit physical organization for protection against multi-node charge collection. Finally, the methodology is utilized to provide critical node separation for a new hardened flip-flop design that reduces the power and area by 31% and 35% respectively compared to a temporal FF with similar hardness. The hardness is verified and compared to other published designs via the proposed systematic simulation approach that comprehends multiple node charge collection and tests resiliency to upsets at all internal and input nodes. Comparison of the hardness, as measured by estimated upset cross-section, is made to other published designs. Additionally, the importance of specific circuit design aspects to achieving hardness is shown. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2015 Electrical engineering Flip-flop Methodology Multi node charge collection Radiation hardening by design Single Event Transient (SET) Single Event Upset (SEU)
5	Durcissement par conception (RHBD) et modélisation des évènements singuliers dans les circuits intégrés numériques en technologies Bulk 65 nm et FDSOI 28 nm / Radiation-Hardening-By-Design (RHDB) and modeling of single event eﬀects in digital circuits manufactured in Bulk 65 nm and FDSOI 28 nm Glorieux, Maximilien 18 July 2014 (has links) La miniaturisation des circuits intégrés numériques tend à augmenter leur sensibilité aux radiations. Ainsi le rayonnement naturel peut induire des événements singuliers et porter atteinte à la fiabilité des circuits.Cette thèse porte sur la modélisation des mécanismes à l'origine de ces événements singuliers et sur le développement de solutions de durcissement par conception permettant de limiter l'impact des radiations sur le taux d'erreur.Dans une première partie, nous avons notamment développé une approche dénommée RWDD (Random-Walk Drift- Diﬀusion) modélisant le transport et la collection de charges au sein d'un circuit, sur la base d'équations physiques sans paramètre d'ajustement. Ce modèle particulaire et sa résolution numérique transitoire permettent de coupler le transport des charges avec un simulateur circuit, tenant ainsi compte de l'évolution temporelle des champs électriques dans la structure. Le modèle RWDD a été intégré avec succès dans une plateforme de simulation capable d'estimer la réponse d'un circuit suite à l'impact d'une particule ionisante.Dans une seconde partie, des solutions de durcissement permettant de limiter l'impact des radiations sur la fiabilité des circuits ont été développées. A l'échelle des cellules élémentaires, de nouvelles bascules robustes aux radiations ont été proposées, en limitant leur impact les performances. Au niveau système, une méthodologie de duplication de l'arbre d'horloge a été développée. Enﬁn, un flot de triplication a été conçu pour les systèmes dont la fiabilité est critique. L'ensemble de ces solutions a été implémenté en technologie 65 nm et UTBB-FDSOI 28 nm et leur efficacité vérifiée expérimentalement. / The extreme technology scaling of digital circuits leads to increase their sensitivity to ionizing radiation, whether in spatial or terrestrial environments. Natural radiation can now induce single event eﬀects in deca-nanometer circuits and impact their reliability.This thesis focuses on the modeling of single event mechanisms and the development of hardening by design solutions that mitigate radiation threat on the circuit error rate.In a ﬁrst part of this work, we have developed a physical model for both the transport and collection of radiation-induced charges in a biased circuit, derived from pure physics-based equations without any ﬁtting parameter. This model is called Random-Walk Drift-Diffusion (RWDD). This particle-level model and its numerical transient solving allows the coupling of the charge collection process with a circuit simulator, taking into account the time variations of the electrical fields in the structure. The RWDD model is able to simulate the behavior of a circuit following a radiation impact, independently of the implemented function and the considered technology.In a second part of our work, hardening solutions that limit radiation impacts on circuit reliability have been developed. At elementary cell level, new radiation-hardened latch architectures have been proposed, with a limited impact on performances. At system level, a clock tree duplication methodology has been proposed, leaning on specific latches. Finally, a triplication flow has been design for critical applications. All these solutions have been implemented in 65 nm and UTBB-FDSOI 28nm technologies and radiation test have been performed to measure their hardening efficiency. Microélectronique Effets des radiations Événement singuliers Durcissement par conception Conception de circuit numériques Modélisation Bascule robuste aux radiation Aléa logique Microelectronic Radiation effects Single event effet Radiation hardening by design Digital design Modeling Radiation hardened latch Single event upset
6	Hardness assurance testing and radiation hardening by design techniques for silicon-germanium heterojunction bipolar transistors and digital logic circuits Sutton, Akil Khamisi 04 May 2009 (has links) Hydrocarbon exploration, global navigation satellite systems, computed tomography, and aircraft avionics are just a few examples of applications that require system operation at an ambient temperature, pressure, or radiation level outside the range covered by military specifications. The electronics employed in these applications are known as "extreme environment electronics." On account of the increased cost resulting from both process modifications and the use of exotic substrate materials, only a handful of semiconductor foundries have specialized in the production of extreme environment electronics. Protection of these electronic systems in an extreme environment may be attained by encapsulating sensitive circuits in a controlled environment, which provides isolation from the hostile ambient, often at a significant cost and performance penalty. In a significant departure from this traditional approach, system designers have begun to use commercial off-the-shelf technology platforms with built in mitigation techniques for extreme environment applications. Such an approach simultaneously leverages the state of the art in technology performance with significant savings in project cost. Silicon-germanium is one such commercial technology platform that demonstrates potential for deployment into extreme environment applications as a result of its excellent performance at cryogenic temperatures, remarkable tolerance to radiation-induced degradation, and monolithic integration with silicon-based manufacturing. In this dissertation the radiation response of silicon-germanium technology is investigated, and novel transistor-level layout-based techniques are implemented to improve the radiation tolerance of HBT digital logic. Bit error rate testing Displacement damage Heterojunction bipolar transistor Radiation effects Radiation hardening by design Silicon germanium Single event upset Ionization Heterojunctions Bipolar transistors Logic circuits Radiation hardening Hardness Germanium compounds Silicon compounds Extreme environments
7	The transactional HW/SW stack for fault tolerant embedded computing / Pilha HW/SW transacional para computacao embarcada tolerante a falhas Ferreira, Ronaldo Rodrigues January 2015 (has links) O desafio de implementar tolerância a falhas em sistemas embarcados advém das restrições físicas de ocupação de área, dissipação de potência e consumo de energia desses sistemas. A necessidade de otimizar essas três restrições de projeto concomitante à computação dentro dos requisitos de desempenho e de tempo-real cria um problema difícil de ser resolvido. Soluções clássicas de tolerância a falhas tais como redundância modular dupla e tripla não são factíveis devido ao alto custo em potência e a falta de um mecanismo para se recuperar erros. Apesar de algumas técnicas existentes reduzirem o overhead de potência e área, essas incorrem em alta degradação de desempenho e muitas vezes assumem um modelo de falhas que não é factível. Essa tese introduz a Pilha de HW/SW Transacional, ou simplesmente Pilha, para gerenciar de maneira eficiente as restrições de área, potência, cobertura de falhas e desempenho. A Pilha introduz uma nova estratégia de compilação que organiza os programas em Blocos Básicos Transacionais (BBT), juntamente com um novo processador, a Arquitetura de Blocos Básicos Transacionais (ABBT), a qual provê detecção e recuperação de erros de grão fino e determinística ao usar o BBT como um contâiner de erros e como unidade de checkpointing. Duas soluções para prover a semântica de execução do BBT em hardware são propostas, uma baseada em software e a outra em hardware. A área, potência, desempenho e cobertura de falhas foram avaliadas através do modelo de hardware do ABBT. A Pilha provê uma cobertura de falhas de 99,35%, com overhead de 2,05 em potência e 2,65 de área. A Pilha apresenta overhead de desempenho de 1,33 e 1,54, dependento do modelo de hardware usado para suportar a semântica de execução do BBT. / Fault tolerance implementation in embedded systems is challenging because the physical constraints of area occupation, power dissipation, and energy consumption of these systems. The need for optimizing these three physical constraints while doing computation within the available performance goals and real-time deadlines creates a conundrum that is hard to solve. Classical fault tolerance solutions such as triple and dual modular redundancy are not feasible due to their high power overhead or lack of efficient and deterministic error recovery. Existing techniques, although some of them reduce the power and area overhead, incur heavy perfor- mance penalties and most of the time do not assume a feasible fault model. This dissertation introduces the Transactional HW/SW Stack, or simply Stack, to effi- ciently manage the area, power, fault coverage, and performance conundrum. The Stack introduces a new compilation strategy that assembles programs into Transac- tional Basic Blocks, together with a novel microprocessor, the TransactiOnal Basic Block Architecture (ToBBA), which provides fine-grained error detection and deter- ministic error rollback and elimination using the Transactional Basic Blocks (TBBs) both as a container for errors and as a small unit of data checkpointing. Two so- lutions to sustain the TBB semantics in hardware are introduced: software- and hardware-based. Stack’s area, power, performance, and coverage were evaluated using ToBBA’s hardware implementation model. The Stack attains an error correc- tion coverage of 99.35% with 2.05 power overhead within an area overhead of 2.65. The Stack also presents a performance overhead of 1.33 or 1.54, depending on the hardware model adopted to support the TBB. Microeletrônica Sistemas embarcados Tolerancia : Falhas Compiler design Coverage Error detection Error recovery Fault injection Hardening by design Latency LLVM Modular redundancy Register file Rollback Single event effects Soft error
8	The transactional HW/SW stack for fault tolerant embedded computing / Pilha HW/SW transacional para computacao embarcada tolerante a falhas Ferreira, Ronaldo Rodrigues January 2015 (has links) O desafio de implementar tolerância a falhas em sistemas embarcados advém das restrições físicas de ocupação de área, dissipação de potência e consumo de energia desses sistemas. A necessidade de otimizar essas três restrições de projeto concomitante à computação dentro dos requisitos de desempenho e de tempo-real cria um problema difícil de ser resolvido. Soluções clássicas de tolerância a falhas tais como redundância modular dupla e tripla não são factíveis devido ao alto custo em potência e a falta de um mecanismo para se recuperar erros. Apesar de algumas técnicas existentes reduzirem o overhead de potência e área, essas incorrem em alta degradação de desempenho e muitas vezes assumem um modelo de falhas que não é factível. Essa tese introduz a Pilha de HW/SW Transacional, ou simplesmente Pilha, para gerenciar de maneira eficiente as restrições de área, potência, cobertura de falhas e desempenho. A Pilha introduz uma nova estratégia de compilação que organiza os programas em Blocos Básicos Transacionais (BBT), juntamente com um novo processador, a Arquitetura de Blocos Básicos Transacionais (ABBT), a qual provê detecção e recuperação de erros de grão fino e determinística ao usar o BBT como um contâiner de erros e como unidade de checkpointing. Duas soluções para prover a semântica de execução do BBT em hardware são propostas, uma baseada em software e a outra em hardware. A área, potência, desempenho e cobertura de falhas foram avaliadas através do modelo de hardware do ABBT. A Pilha provê uma cobertura de falhas de 99,35%, com overhead de 2,05 em potência e 2,65 de área. A Pilha apresenta overhead de desempenho de 1,33 e 1,54, dependento do modelo de hardware usado para suportar a semântica de execução do BBT. / Fault tolerance implementation in embedded systems is challenging because the physical constraints of area occupation, power dissipation, and energy consumption of these systems. The need for optimizing these three physical constraints while doing computation within the available performance goals and real-time deadlines creates a conundrum that is hard to solve. Classical fault tolerance solutions such as triple and dual modular redundancy are not feasible due to their high power overhead or lack of efficient and deterministic error recovery. Existing techniques, although some of them reduce the power and area overhead, incur heavy perfor- mance penalties and most of the time do not assume a feasible fault model. This dissertation introduces the Transactional HW/SW Stack, or simply Stack, to effi- ciently manage the area, power, fault coverage, and performance conundrum. The Stack introduces a new compilation strategy that assembles programs into Transac- tional Basic Blocks, together with a novel microprocessor, the TransactiOnal Basic Block Architecture (ToBBA), which provides fine-grained error detection and deter- ministic error rollback and elimination using the Transactional Basic Blocks (TBBs) both as a container for errors and as a small unit of data checkpointing. Two so- lutions to sustain the TBB semantics in hardware are introduced: software- and hardware-based. Stack’s area, power, performance, and coverage were evaluated using ToBBA’s hardware implementation model. The Stack attains an error correc- tion coverage of 99.35% with 2.05 power overhead within an area overhead of 2.65. The Stack also presents a performance overhead of 1.33 or 1.54, depending on the hardware model adopted to support the TBB. Microeletrônica Sistemas embarcados Tolerancia : Falhas Compiler design Coverage Error detection Error recovery Fault injection Hardening by design Latency LLVM Modular redundancy Register file Rollback Single event effects Soft error
9	The transactional HW/SW stack for fault tolerant embedded computing / Pilha HW/SW transacional para computacao embarcada tolerante a falhas Ferreira, Ronaldo Rodrigues January 2015 (has links) O desafio de implementar tolerância a falhas em sistemas embarcados advém das restrições físicas de ocupação de área, dissipação de potência e consumo de energia desses sistemas. A necessidade de otimizar essas três restrições de projeto concomitante à computação dentro dos requisitos de desempenho e de tempo-real cria um problema difícil de ser resolvido. Soluções clássicas de tolerância a falhas tais como redundância modular dupla e tripla não são factíveis devido ao alto custo em potência e a falta de um mecanismo para se recuperar erros. Apesar de algumas técnicas existentes reduzirem o overhead de potência e área, essas incorrem em alta degradação de desempenho e muitas vezes assumem um modelo de falhas que não é factível. Essa tese introduz a Pilha de HW/SW Transacional, ou simplesmente Pilha, para gerenciar de maneira eficiente as restrições de área, potência, cobertura de falhas e desempenho. A Pilha introduz uma nova estratégia de compilação que organiza os programas em Blocos Básicos Transacionais (BBT), juntamente com um novo processador, a Arquitetura de Blocos Básicos Transacionais (ABBT), a qual provê detecção e recuperação de erros de grão fino e determinística ao usar o BBT como um contâiner de erros e como unidade de checkpointing. Duas soluções para prover a semântica de execução do BBT em hardware são propostas, uma baseada em software e a outra em hardware. A área, potência, desempenho e cobertura de falhas foram avaliadas através do modelo de hardware do ABBT. A Pilha provê uma cobertura de falhas de 99,35%, com overhead de 2,05 em potência e 2,65 de área. A Pilha apresenta overhead de desempenho de 1,33 e 1,54, dependento do modelo de hardware usado para suportar a semântica de execução do BBT. / Fault tolerance implementation in embedded systems is challenging because the physical constraints of area occupation, power dissipation, and energy consumption of these systems. The need for optimizing these three physical constraints while doing computation within the available performance goals and real-time deadlines creates a conundrum that is hard to solve. Classical fault tolerance solutions such as triple and dual modular redundancy are not feasible due to their high power overhead or lack of efficient and deterministic error recovery. Existing techniques, although some of them reduce the power and area overhead, incur heavy perfor- mance penalties and most of the time do not assume a feasible fault model. This dissertation introduces the Transactional HW/SW Stack, or simply Stack, to effi- ciently manage the area, power, fault coverage, and performance conundrum. The Stack introduces a new compilation strategy that assembles programs into Transac- tional Basic Blocks, together with a novel microprocessor, the TransactiOnal Basic Block Architecture (ToBBA), which provides fine-grained error detection and deter- ministic error rollback and elimination using the Transactional Basic Blocks (TBBs) both as a container for errors and as a small unit of data checkpointing. Two so- lutions to sustain the TBB semantics in hardware are introduced: software- and hardware-based. Stack’s area, power, performance, and coverage were evaluated using ToBBA’s hardware implementation model. The Stack attains an error correc- tion coverage of 99.35% with 2.05 power overhead within an area overhead of 2.65. The Stack also presents a performance overhead of 1.33 or 1.54, depending on the hardware model adopted to support the TBB. Microeletrônica Sistemas embarcados Tolerancia : Falhas Compiler design Coverage Error detection Error recovery Fault injection Hardening by design Latency LLVM Modular redundancy Register file Rollback Single event effects Soft error
10	Design and characterization of BiCMOS mixed-signal circuits and devices for extreme environment applications Cardoso, Adilson Silva 12 January 2015 (has links) State-of-the-art SiGe BiCMOS technologies leverage the maturity of deep-submicron silicon CMOS processing with bandgap-engineered SiGe HBTs in a single platform that is suitable for a wide variety of high performance and highly-integrated applications (e.g., system-on-chip (SOC), system-in-package (SiP)). Due to their bandgap-engineered base, SiGe HBTs are also naturally suited for cryogenic electronics and have the potential to replace the costly de facto technologies of choice (e.g., Gallium-Arsenide (GaAs) and Indium-Phosphide (InP)) in many cryogenic applications such as radio astronomy. This work investigates the response of mixed-signal circuits (both RF and analog circuits) when operating in extreme environments, in particular, at cryogenic temperatures and in radiation-rich environments. The ultimate goal of this work is to attempt to fill the existing gap in knowledge on the cryogenic and radiation response (both single event transients (SETs) and total ionization dose (TID)) of specific RF and analog circuit blocks (i.e., RF switches and voltage references). The design approach for different RF switch topologies and voltage references circuits are presented. Standalone Field Effect Transistors (FET) and SiGe HBTs test structures were also characterized and the results are provided to aid in the analysis and understanding of the underlying mechanisms that impact the circuits' response. Radiation mitigation strategies to counterbalance the damaging effects are investigated. A comprehensive study on the impact of cryogenic temperatures on the RF linearity of SiGe HBTs fabricated in a new 4th-generation, 90 nm SiGe BiCMOS technology is also presented. SiGe RF switches BiCMOS FET-based SOI PIN diode BiCMOS circuits Radiation hardening by design Transient response Transient radiation effects Extreme environments Mixed-signal circuits Silicon-germanium Single-pole single-throw(SPST) Single-pole four-throw(SP4T) Single-pole double-throw(SPDT) Voltage references Cryogenic temperatures Large-signal linearity Non-linearities Small-signal linearity Large-signal linearity Radiation Single event transient (SET) Total ionizing dose (TID) Radiation Precision voltage reference Bandgap reference (BGR) Bulk FET

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