PCB access impedances extraction method of in-situ integrated circuit

This article describes an extraction technique of input and output impedances of integrated circuits (ICs) implemented onto the printed circuit boards (PCBs). The feasibility of the technique is illustrated with a proof-of-concept (POC) constituted by two ICs operating in a typically transmitter-receiver (Tx-Rx) circuit. The POC system is assumed composed of three different blocks of emitter signal source, load and interconnect passive network. This latter one is assumed defined by its chain matrix known from its electrical and physical characteristics. The proposed impedance extraction method is elaborated from the given signals at the transmitter output and receiver input. The terminal access impedances are formulated in function of the parameters of the interconnect system chain matrix. The feasibility of the method is checked with a passive circuit constituted by transmission lines driven by voltage source with RL-series network internal impedance and loaded at the output by the RC-parallel network. Good correlation between the access impedance reference and calculated is found

Bandwidth Enhancement Techniques For Cmos Transimpedance Amplifier

Tez (Doktora) -- İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, 2016Thesis (PhD) -- İstanbul Technical University, Institute of Science and Technology, 2016CMOS Transferempedans Kuvvetlendiricinin bandgenis¸lig˘ i bas¸arımını gelis¸tirmeye yönelik teknikler haberles¸me teknolojisinde ve uygulamalarında ortaya çıkan hızlı gelis¸meler ve uygulamalar verilere hızlı eris¸im avantajı yanında hızlı hesaplama ve haberles¸me tekniklerine imkan veren bir bilgi çag˘ ını ortaya çıkarmıs¸tır. Sürekli artan hızlı bilgi transferi ihtiyacı, hızlı elemanların ve tümdevrelerin tasarımına yönelik aras¸tırmalara liderlik eden optik haberles¸me teknig˘ ini dog˘ urmus¸tur. Veri iletimi için mevcut ortamlar arasında optik fiber yapıları en iyi bas¸arımı sunmaktadır. Günümüzde optik fiberler çok yog˘ un sayısal veri transferinde genis¸ kullanım alanı bulmaktadır. Yog˘ un veri aktarımı kilometrelerce uzunlukta optik fiberler üzerinde önemli bir kayıp olmaksızın yapılabilmektedir. Normal s¸artlarda, is¸aret aktarımının ıs¸ık ile yapılması durumunda ortaya çıkan kayıp elektriksel yolla yapılan aktarıma gore daha düs¸üktür. Optik fiberler genel bas¸arımı iyiles¸tirmenin yanında düs¸ük maliyet avantajını da sunmaktadır. En yüksek teknolojilerde, optik fiber elemanları ve sistemleri çok yog˘ un veri aktarımı amacıyla kullanılmaktadır. Sonuç olarak optik fiber teknolojisi düs¸ük kayıpla çok yog˘ un veri aktarımını az maliyetle sunabilen bir teknoloji olarak günümüzde çok önemli bir konuma sahiptir. Genel olarak, optik haberles¸me sistemlerinde kullanılan analog devreler Galyum Arsenik (GaAs) veya Indiyum Fosfid (InP) teknolojileri ile üretilmektedir. Bu prosesler yüksek hızlı devreler için olus¸turulmakta olup optik haberles¸me sistemlerinin ihtiyaç duydug˘ u yüksek band genis¸lig˘ ine sahip devreleri üretmek için genellikle tek alternatif olarak kars¸ımıza çıkmaktadırlar. Bununla birlikte, CMOS proseslerinde ortaya çıkan hızlı gelis¸meler sayesinde daha yüksek bas¸arımlara sahip analog devreleri CMOS proses kullanarak tasarlama ve gerçekles¸tirme imkanları gittikçe artmaktadır. CMOS prosesin tercih edilmesine sebep olan en önemli avantaj maliyetlerde ortaya çıkan büyük düs¸üs¸tür. CMOS proseslerin maliyetinin düs¸ük olmasının sebebi, büyük alan kullanımı gerektiren sayısal devre gerçekles¸tirmelerinde çok genis¸ bir kullanıma sahip olmasıdır. CMOS prosesin dig˘ er bir avantajı sayısal ve analog devrelerin aynı taban üzerinde gerçekles¸tirilmesine imkan vermesidir. Transferempedans kuvvetlendirici (TIA) optik haberles¸me alıcılarındaki ilk blok olup giris¸indeki akımı çıkıs¸ında gerilime dönüs¸türmektedir. Tipik bir TIA’nın önemli bas¸arım ihtiyaçları genis¸ bandgenis¸lig˘ i, yüksek transferempedans kazancı, düs¸ük gürültü, düs¸ük güç tüketimi ve küçük grup geçikme deg˘ is¸im aralıg˘ ıdır. Nano teknolojilerdeki güncel gelis¸meler, optik alıcıların giris¸ katı uygulamalarında gerekli kolay bir s¸ekilde elde edilemeyen bas¸arımları sag˘ layabilen CMOS Transfer- empedans Kuvvetlendiricinin (TIA) tasarımını ekonomik hale getirmis¸tir. TIA tasarımında dikkat edilmesi gereken iki önemli mesele bandgenis¸lig˘ i ve giris¸ hassasiyetidir. TIA’nın bandgenis¸lig˘ i genellikle giris¸teki parasitic kapasite tarafından sınırlanmaktadır. TIA’nın bandgenis¸lig˘ i fotodiyot kapasitesi, transistor giris¸ kapasitesi ve transistor giris¸ direncinin belirledig˘ i RC zaman sabiti ile bulunabilir. Giris¸ hassasiyeti ise TIA’nın giris¸ gürültü akımından etkilenmektedir. Bundan dolayı TIA’nın bandgenis¸lig˘ i ve giris¸ is¸areti hassasiyeti bas¸arımlarını optimum bir s¸ekilde temin eden uygun devre topolojisinin belirlenmesi önemli bir meseledir. Bu tez, CMOS teknolojisi kullanan Transferempedans Kuvvetlendiricinin band- genis¸lig˘ i bas¸arımını gelis¸tirmeye yönelik yeni teknikler sunan bir çalıs¸madır. CMOS TIA’nın bandgenis¸lig˘ i bas¸arımını iyiles¸tirmeye yönelik farklı yaklas¸ımlar tez içerisinde gösterilmektedir. Bundan bas¸ka, bu çalıs¸ma transferempedansı kuvvetlendiricinin analizini ve tasarımını tam olarak anlamak için gerekli altyapı bilgisini de sunmaktadır. Bu tezde, sistemle devre tasarımı arasındaki bos¸lug˘ u doldurmak için s¸unlar yapılmıs¸tır: - Band genis¸lig˘ i bas¸arımının arttırılmasının matematiksel analizlerle anlas¸ılması. - Gerçekles¸tirilebilir yeni devre yapılarının tanıtılması. - Teklif edilen tasarımların CMOS teknolojisiyle gerçekles¸tirilebilirlig˘ inin kapsamlı ve detaylı simülasyonlar kullanılarak gösterilmesi. Sunulan yeni devre yapılarının ilki olarak, negatif empedans devresinin bandgenis¸lig˘ i artıs¸ı için kullanılabileceg˘ i bu tezde gösterilmis¸ olup bu teknik bu tezde TIA’nın çıkıs¸ kutpu için uygulanmaktadır. Bandgenis¸lig˘ i, kazancı (gmRout) arttırarak ve çıkıs¸ta aynı zaman sabiti korunarak arttırılabilir. Çıkıs¸ direnci arttırılarak kazanç (A) yükseltilebilir. Çıkıs¸ direnci çıkıs¸a uygulanacak bir negative direnç devresi ile arttırılabilir. Çıkıs¸ta aynı zaman sabitini korumak için ise negatif kapasite devresi kullanılabilir. Daha yüksek kazanç deg˘ eri (A) rezistif geribesleme sayesinde giris¸ direncini azaltarak giris¸ kutbunun yükselmesini sag˘ lamaktadır. Sonuç olarak, bandgenis¸lig˘ i bas¸arımında bir iyiles¸tirme elde edilebilmektedir. Teklif edilen topoloji ile 7GHz bandgenis¸lig˘ ine ve 54.3dB’lik kazanca sahip bir TIA tasarlanmıs¸tır. Teklif edilen TIA’nın 1.8V’luk besleme kaynag˘ ından çektig˘ i toplam güç 29mW’tır. Teklif edilen TIA’nın 0.18um CMOS proses ile post-serimi yapılmıs¸tır. Benzetimle elde edilmis¸ giris¸ gürültü akım yog˘ unlug˘ u 5.9pA/ Hz olup kapladıg˘ ı alan 230umX45um olmus¸tur. Tezde bir sonraki çalıs¸mada es¸les¸tirme teknig˘ i kullanılarak genis¸ bantlı bs¸r TIA tasarlanmıs¸tır. Giris¸te seri empedans es¸les¸tirme teknig˘ i ve çıkıs¸ta T tipi es¸les¸tirme yapısı birlikte kullanılarak TIA’nın bandgenis¸lig˘ i bas¸arımının iyi bir düzeyde iyiles¸tirilebileceg˘ i gösterilmis¸tir. Bu yaklas¸ım 0.18um CMOS teknolojisi ile yapılmıs¸ bir tasarım örneg˘ i ile desteklenmis¸tir. Post serim sonuçları 50fF’lık bir fotodiyot kapasitesi için 20GHz’lik bandgenis¸lig˘ i, 52.6dB’lik transferdirenci kazancı, 8.7pA/ Hz ‘lik giris¸ gürültü akımı ve 3pS’den daha az grup geçikmesi bas¸arımılarını vermis¸tir. Bu TIA uygulaması 1.8V’luk besleme kaynag˘ ından 1.3mW güç çekmis¸tir. Tezin üçüncü as¸amasında TIA band genis¸lig˘ i bas¸arımını arttırmaya yönelik bas¸ka bir yapı sunulmaktadır. Bu yapı, literatürde bilinen regule edilmis¸ ortak geçitli mimari ile birlikte farklı rezonans frekanslarına sahip iki rezonans devresinin paralel kullanımını içermektedir. Teklif edilen TIA devresinde, kapasite dejenarasyon ve seri endüktif tepe teknikleri kutup-sıfır kompanzasyonu için kullanılmıs¸tır. 100fF’lık fotodiyot kapasitesine sahip bir TIA 0.18um CMOS prosesi ili tasarlanmıs¸tır. Post-serim sonuçları 13GHz’lik bandgenis¸lig˘ i, 53dB’lik transferdirenci kazancı, 24pA/ Hz ‘lik xxvi giris¸ gürültü akımı ve 5pS’den daha az grup geçikmesi bas¸arımılarını vermis¸tir. Bu TIA uygulaması 1.8V’luk besleme kaynag˘ ından 11mW güç çekmis¸tir. Tezin dördüncü as¸amasında, regule edilmis¸ ortak geçitli mimari kullanan TIA’nın bandgenis¸lig˘ i bas¸arımını arttırmaya yönelik bir teknik tanıtılmıs¸tır. Bu teknik, resistif kompanzasyon teknig˘ ini ve merdiven es¸les¸tirme yapısını bir kaskod akım kaynag˘ ı ile birlikte kullanmaya dayanmaktadır. Bu yapının bas¸arımını göstermek amacıyla, 0.18um CMOS prosesi ile bir tasarım yapılmıs¸tır. Post-serim sonuçları 8.4GHz’lik bandgenis¸lig˘ i, 51.3dB’lik transferdirenci kazancı, 20pA/ Hz ‘lik giris¸ gürültü akımı ve 4pS’den daha az grup geçikmesi bas¸arımılarını vermis¸tir. Bu TIA uygulaması 1.8V’luk besleme kaynag˘ ından 17.8mW güç çekmis¸tir. Tezin son as¸amasında, tezde sunulan teknikler ve yapıların kendi aralarında kars¸ılas¸tırılması verilmektedir. Kars¸ılas¸tırma öncelikli olarak band genis¸lig˘ i, transferempedansı kazancı, gürültü, güç tüketimi, grup geçikme deg˘ is¸im aralıg˘ ı ve kapladıg˘ ı alan için yapılmaktadır. Bunlara ek olarak, sunulan yapıların kullandıg˘ ı tekniklerin avantajlı yanları ile birlikte (kararlılık üzerinde olus¸abilecek negatif etkiler gibi) dezavantajlı tarafları da tezin son as¸amasında verilmektedir. Tezin son as¸amasında yapılan kars¸ılas¸tırmalar, en iyi bant genis¸lig˘ i bas¸arımının es¸les¸tirme teknig˘ ini kullanan yapıdan elde edildig˘ ini göstermektedir. Bununla birlikte dig˘ er yapıların da band genis¸lig˘ i bas¸arımı üzerinde önemli iyiles¸tirmeler yaptıg˘ ı ortaya konulmaktadır. Gürültü açısından ise en yüksek bas¸arımın negatif empedans teknig˘ ini kullanan yapıda elde edildig˘ i görülmektedir. Bu yapı aynı zamanda düs¸ük alan kullanımı imkanı da sunmaktadır. Tezde sunulan dig˘ er iki yapı ise özellikle yüksek deg˘ erli fotodiyot kapasiteleri için incelenmis¸ olup band genis¸lig˘ i bas¸arımı üzerinde önemli iyiles¸tirmeler yaptıkları gösterilmektedir. Sonuç olarak, bu tezde transferempedans kuvvetlendiricinin bandgenis¸lig˘ i bas¸arımını iyiles¸tiren farklı teknikler sunulmakta olup bu teknikler ayrıntılı ve kars¸ılas¸tırmalı olarak incelenmektedir. Tezde verilen sonuçlar sunulan yeni tekniklerin bas¸arımlarının yüksek oldug˘ unu ve literature yeni ve güçlü alternatfiler sunuldug˘ unu göstermektedir. Tezde sunulan yaklas¸ımların ve tekniklerin gelecekte yapılacak benzer aras¸tırmalara hem yardımcı olacak hem de referans olacak nitelikte oldug˘ u düs¸ünülmektedir.The accelerated development of integrated systems in the communication technology and their application are among the significant technologies that have developed the information era by empowering high-speed computation and communication technique besides high-speed access to stored data. The continuous growth demand for high-speed transport of information has rekindled optical communications, leading to derived research on high-speed device and integrated circuit design. Among the available medium to transfer the data, optical fibers have the best performance. Optical fibers are very common these days to transport very high rate digital data. Such high speed data rates can be transported over kilometers of optical fiber and without significant loss. Normally loss is very low when the signal is transmitted using light rather than electrical signal. These fibers also have the advantage of being low cost in addition to improvement of performance. In state-of-the-art technology, fiber optic devices and systems are evidently employed to realize very high data rates. Fiber optic communication is a solution because high data rates can be transmitted through this high capacity cable with high performance. Traditionally, analog circuits used in optical communication systems are implemented using Gallium Arsenide (GaAs) or Indium Phosphide (InP) technologies. These processes are designed for high speed circuits, and have been traditionally the only technologies able to produce the high bandwidth circuits required in optical communication systems. However, due to the aggressive scaling of the CMOS process, it is now becoming possible to design high performance analog circuits in CMOS. The primary advantage of moving to a CMOS process is a dramatic reduction in cost due to its widespread use in high volume digital circuits. Another advantage of using CMOS is its ability to integrate digital and analog circuits onto the same substrate. Transimpedance amplifier (TIAs) is the first building block in the optical communication receiver that converts the small signal current to a corresponding output voltage signal. The important requirements of a typical TIA are large bandwidth, high transimpedance gain, low noise, low power consumption, and small group delay variation. Current developments in nanoscale technologies made it economically feasible to design CMOS transimpedance amplifier (TIA) that satisfies the stringent performances necessary for the front-end optical transceivers applications such as low power, low cost and high integration which offers the most economical solution in the consumer application market. In designing of TIA, the two major factors that must be considered are the bandwidth and the input sensitivity. The bandwidth of TIA is usually limited by the parasitic capacitance at the input stage, and it can be calculated by its RC time constant contributed by photodiode capacitance, parasitic capacitance and input resistance of the amplifier. The sensitivity is affected by the input current noise of the TIA. Therefore it is challenge to choose the suitable circuit topology that provides an optimal trade-off between bandwidth and input signal sensitivity for TIA. This thesis is an attempt toward providing novel techniques to extend the bandwidth of the transimpedance amplifier using CMOS technology. Different approaches used to improve the bandwidth of CMOS TIAs are covered. Moreover, this research provides the necessary background knowledge to fully understand the analysis and design of the transimpedance amplifier (TIA). Bridging the gap between system and circuit design is done by: Understanding the bandwidth expansion by mathematical analysis. Introducing new circuit architectures that can be realized. Demonstrating implementation of the proposed designs using extensive simulations in CMOS technology. It is shown in this thesis that, using a negative impedance NI circuit can be used for bandwidth extension. In our application, the negative impedance is incorporated into the output pole of TIA. The bandwidth can be improved by increasing the gain (A = gmRout ) and by maintaining the same time constant at the output pole. A better gain A can be obtained if the output resistance Rout is increased. Increasing Rout can be done by placing a negative resistance RIN in parallel with the output resistance Rout . In order to maintain the same time constant at the output node, a negative capacitance can be used. It have been reported that, the shunt feedback architecture is used to improve the bandwidth of TIA. Increasing the gain A effectively decreases the input resistance and hence increase the frequency of the input pole due to feedback. As a result, an improvement of the bandwidth can be obtained. Using the proposed topology, a wide band transimpedance amplifier with a bandwidth of 7 GH z and transimpedance gain of 54.3 dBΩ is achieved. The total power consumption of the proposed TIA from the 1.8 V power supply is 29 mW . The TIA is designed in 0.18 µ m CMOS technology. The simulated input referred noise current spectral density is 5.9 pA/√H z and the TIA occupies 230µ m × 45µ m of area. Furthermore, a wide band TIA is designed using the matching technique. It is shown that by simultaneously using of series input matching topology and T-output matching network, the bandwidth of the TIA can be obviously improved. This methodology is supported by a design example in a 0.18 µ m CMOS technology. The post layout simulation results show a bandwidth of 20 GH z with 50 f F photodiode capacitance, a transimpedance gain of 52.6 dBΩ, 11 pA/√H z input referred noise and group delay less than 8.3 ps. The TIA dissipates 1.3 mW from a 1.8 V supply voltage. In addition, a new design possessing to extend the bandwidth of the TIA is presented. This TIA employs a parallel combination of two series resonate circuits with different resonate frequencies on the conventional regulated common gate (RGC) architecture. In the proposed TIA, a capacitance degeneration and series inductive peaking technique are used for pole-zero elimination. The TIA is implemented in a 0.18 µ m CMOS process, where a 100 f F photodiode is considered. The post layout simulation results show a transimpedance gain of 53 dBΩ transimpedance gain along with a 13 GH z bandwidth. The designed TIA consumes 11 mW from a 1.8 V supply, and its group-delay variation is 5 ps with 24 pA/√H z input referred noise. xxii In the last phase of the work, a technique to enhance the bandwidth of the regulated common gate (RCG) transimpedance amplifier is described. The technique is based on using a cascode current mirror with resistive compensation technique and a ladder matching network. In order to verify the operation and the performance of the proposed technique, a CMOS design example is designed using the 0.18µ m CMOS process technology. The post layout simulation results show that, the proposed TIA achieved a bandwidth of 8.4 GH z, a transimpedance gain of 51.3 dBΩ and input referred noise current spectral density of 20 pA/√H z. The average group-delay variation is 4 ps over the bandwidth and the TIA consumes 17.8 mW from a 1.8 V supply. To sum up, this thesis focuses on various design techniques of transimpedance amplifier (TIA) that improves the bandwidth performance. We believe that, our approaches and techniques exhibit a path which other future researchers can follow and as well refer to as their researching domain and also could be used in their research applications.DoktoraPh

Advancement on the Susceptibility of Analog Front-Ends to EMI

L'abstract è presente nell'allegato / the abstract is in the attachmen

Model Order Reduction

An increasing complexity of models used to predict real-world systems leads to the need for algorithms to replace complex models with far simpler ones, while preserving the accuracy of the predictions. This three-volume handbook covers methods as well as applications. This third volume focuses on applications in engineering, biomedical engineering, computational physics and computer science

Low-Power Design of Digital VLSI Circuits around the Point of First Failure

As an increase of intelligent and self-powered devices is forecasted for our future everyday life, the implementation of energy-autonomous devices that can wirelessly communicate data from sensors is crucial. Even though techniques such as voltage scaling proved to effectively reduce the energy consumption of digital circuits, additional energy savings are still required for a longer battery life. One of the main limitations of essentially any low-energy technique is the potential degradation of the quality of service (QoS). Thus, a thorough understanding of how circuits behave when operated around the point of first failure (PoFF) is key for the effective application of conventional energy-efficient methods as well as for the development of future low-energy techniques. In this thesis, a variety of circuits, techniques, and tools is described to reduce the energy consumption in digital systems when operated either in the safe and conservative exact region, close to the PoFF, or even inside the inexact region. A straightforward approach to reduce the power consumed by clock distribution while safely operating in the exact region is dual-edge-triggered (DET) clocking. However, the DET approach is rarely taken, primarily due to the perceived complexity of its integration. In this thesis, a fully automated design flow is introduced for applying DET clocking to a conventional single-edge-triggered (SET) design. In addition, the first static true-single-phase-clock DET flip-flop (DET-FF) that completely avoids clock-overlap hazards of DET registers is proposed. Even though the correct timing of synchronous circuits is ensured in worst-case conditions, the critical path might not always be excited. Thus, dynamic clock adjustment (DCA) has been proposed to trim any available dynamic timing margin by changing the operating clock frequency at runtime. This thesis describes a dynamically-adjustable clock generator (DCG) capable of modifying the period of the produced clock signal on a cycle-by-cycle basis that enables the DCA technique. In addition, a timing-monitoring sequential (TMS) that detects input transitions on either one of the clock phases to enable the selection of the best timing-monitoring strategy at runtime is proposed. Energy-quality scaling techniques aimat trading lower energy consumption for a small degradation on the QoS whenever approximations can be tolerated. In this thesis, a low-power methodology for the perturbation of baseline coefficients in reconfigurable finite impulse response (FIR) filters is proposed. The baseline coefficients are optimized to reduce the switching activity of the multipliers in the FIR filter, enabling the possibility of scaling the power consumption of the filter at runtime. The area as well as the leakage power of many system-on-chips is often dominated by embedded memories. Gain-cell embedded DRAM (GC-eDRAM) is a compact, low-power and CMOS-compatible alternative to the conventional static random-access memory (SRAM) when a higher memory density is desired. However, due to GC-eDRAMs relying on many interdependent variables, the adaptation of existing memories and the design of future GCeDRAMs prove to be highly complex tasks. Thus, the first modeling tool that estimates timing, memory availability, bandwidth, and area of GC-eDRAMs for a fast exploration of their design space is proposed in this thesis

A Finite Domain Constraint Approach for Placement and Routing of Coarse-Grained Reconfigurable Architectures

Scheduling, placement, and routing are important steps in Very Large Scale Integration (VLSI) design. Researchers have developed numerous techniques to solve placement and routing problems. As the complexity of Application Specific Integrated Circuits (ASICs) increased over the past decades, so did the demand for improved place and route techniques. The primary objective of these place and route approaches has typically been wirelength minimization due to its impact on signal delay and design performance. With the advent of Field Programmable Gate Arrays (FPGAs), the same place and route techniques were applied to FPGA-based design. However, traditional place and route techniques may not work for Coarse-Grained Reconfigurable Architectures (CGRAs), which are reconfigurable devices offering wider path widths than FPGAs and more flexibility than ASICs, due to the differences in architecture and routing network. Further, the routing network of several types of CGRAs, including the Field Programmable Object Array (FPOA), has deterministic timing as compared to the routing fabric of most ASICs and FPGAs reported in the literature. This necessitates a fresh look at alternative approaches to place and route designs. This dissertation presents a finite domain constraint-based, delay-aware placement and routing methodology targeting an FPOA. The proposed methodology takes advantage of the deterministic routing network of CGRAs to perform a delay aware placement

Um amplificador de transimpedância de ganho variável para aplicação em osciladores baseados em MEMS

Orientador: José Alexandre DinizDissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Elétrica e de ComputaçãoResumo: Um amplificador de transimpedância (TIA) de ganho variável é apresentado. Implementado em tecnologia 0,18 'mi'm, o projeto relatado possui a finalidade de prover um amplificador de sustentação para osciladores baseados em ressonadores do tipo MEMS (Micro-Electro-Mechanical System). Entre outros, as peculiaridades de projeto envolvem um desafiante compromisso entre Ganho, Largura de Banda, Ruído e Consumo de potência. Sendo assim, o amplificador foi implementado através do cascateamento de quatro estágios de ganho similares, lançando-se mão de realimentação do tipo shunt-shunt para diminuir as impedâncias de entrada e saída. Através do emprego de um estágio de ganho variável, uma alta faixa dinâmica de ganho é alcançada (53 dB), com um ganho máximo de transimpedância de 118 dB'ômega'...Observação: O resumo, na íntegra, poderá ser visualizado no texto completo da tese digitalAbstract: A variable gain Transimpedance Amplifier (TIA) is presented. Realized in 0.18 'mi'm technology, this amplifier was conceived with the purpose of providing oscillation sustaining for Micro-Electro-Mechanical System (MEMS) based oscillators. Facing a quite challenging trade-off between Gain, Bandwidth, Noise and Power consumption, the TIA was implemented through the cascade of four similar gain stages, with the application of shunt-shunt feedback to lower both input and output resistances. With the employment of a variable-gain stage, this TIA presents a large gain tunability of 53 dB, with a also large maximum transimpedance gain of 118 dB'omega'...Note: The complete abstract is available with the full electronic documentMestradoEletrônica, Microeletrônica e OptoeletrônicaMestre em Engenharia Elétric

Modeling EMI Resulting from a Signal Via Transition Through Power/Ground Layers

Signal transitioning through layers on vias are very common in multi-layer printed circuit board (PCB) design. For a signal via transitioning through the internal power and ground planes, the return current must switch from one reference plane to another reference plane. The discontinuity of the return current at the via excites the power and ground planes, and results in noise on the power bus that can lead to signal integrity, as well as EMI problems. Numerical methods, such as the finite-difference time-domain (FDTD), Moment of Methods (MoM), and partial element equivalent circuit (PEEC) method, were employed herein to study this problem. The modeled results are supported by measurements. In addition, a common EMI mitigation approach of adding a decoupling capacitor was investigated with the FDTD method

Design of Fully-Integrated High-Resolution Radars in CMOS and BiCMOS Technologies

The RADAR, acronym that stands for RAdio Detection And ranging, is a device that uses electromagnetic waves to detect the presence and the distance of an illuminated target. The idea of such a system was presented in the early 1900s to determine the presence of ships. Later on, with the approach of World War II, the radar gained the interest of the army who decided to use it for defense purposes, in order to detect the presence, the distance and the speed of ships, planes and even tanks. Nowadays, the use of similar systems is extended outside the military area. Common applications span from weather surveillance to Earth composition mapping and from flight control to vehicle speed monitoring. Moreover, the introduction of new ultrawideband (UWB) technologies makes it possible to perform radar imaging which can be successfully used in the automotive or medical field. The existence of a plenty of known applications is the reason behind the choice of the topic of this thesis, which is the design of fully-integrated high-resolution radars. The first part of this work gives a brief introduction on high resolution radars and describes its working principle in a mathematical way. Then it gives a comparison between the existing radar types and motivates the choice of an integrated solution instead of a discrete one. The second part concerns the analysis and design of two CMOS high-resolution radar prototypes tailored for the early detection of the breast cancer. This part begins with an explanation of the motivations behind this project. Then it gives a thorough system analysis which indicates the best radar architecture in presence of impairments and dictates all the electrical system specifications. Afterwards, it describes in depth each block of the transceivers with particular emphasis on the local oscillator (LO) generation system which is the most critical block of the designs. Finally, the last section of this part presents the measurement results. In particular, it shows that the designed radar operates over 3 octaves from 2 to 16GHz, has a conversion gain of 36dB, a flicker-noise-corner of 30Hz and a dynamic range of 107dB. These characteristics turn into a resolution of 3mm inside the body, more than enough to detect even the smallest tumor. The third and last part of this thesis focuses on the analysis and design of some important building blocks for phased-array radars, including phase shifter (PHS), true time delay (TTD) and power combiner. This part begins with an exhaustive introduction on phased array systems followed by a detailed description of each proposed lumped-element block. The main features of each block is the very low insertion loss, the wideband characteristic and the low area consumption. Finally, the major effects of circuit parasitics are described followed by simulation and measurement results