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A RISC-V Vector Processor With Simultaneous-Switching Switched-Capacitor DC-DC Converters in 28 nm FDSOI
This work demonstrates a RISC-V vector microprocessor implemented in 28 nm FDSOI with fully integrated simultaneous-switching switched-capacitor DC-DC (SC DC-DC) converters and adaptive clocking that generates four on-chip voltages between 0.45 and 1 V using only 1.0 V core and 1.8 V IO voltage inputs. The converters achieve high efficiency at the system level by switching simultaneously to avoid charge-sharing losses and by using an adaptive clock to maximize performance for the resulting voltage ripple. Details about the implementation of the DC-DC switches, DC-DC controller, and adaptive clock are provided, and the sources of conversion loss are analyzed based on measured results. This system pushes the capabilities of dynamic voltage scaling by enabling fast transitions (20 ns), simple packaging (no off-chip passives), low area overhead (16%), high conversion efficiency (80%-86%), and high energy efficiency (26.2 DP GFLOPS/W) for mobile devices
Phased Array Systems in Silicon
Phased array systems, a special case of MIMO systems, take advantage of spatial directivity and array gain to increase spectral efficiency. Implementing a phased array system at high frequency in a commercial silicon process technology presents several challenges. This article focuses on the architectural and circuit-level trade-offs involved in the design of the first silicon-based fully integrated phased array system operating at 24 GHz. The details of some of the important circuit building blocks are also discussed. The measured results demonstrate the feasibility of using integrated phased arrays for wireless communication and vehicular radar applications at 24 GHz
Solar array fed synchronous reluctance motor driven water pump : an improved performance under partial shading conditions
An improved performance of a photovoltaic (PV) pumping system employing a synchronous reluctance motor (SynRM) under partial shading conditions is proposed. The system does not include the dc-dc converter that is predominantly being utilized for maximizing the output power of the PV array. In addition, storage batteries are also not contained. A conventional inverter connected directly to the PV array is used to drive the SynRM. Further, a control strategy is proposed to drive the inverter so that the maximum output power of the PV array is achieved while the SynRM is working at the maximum torque per Ampere condition. Consequently, this results in an improved system efficiency and cost. Moreover, two maximum power point tracking (MPPT) techniques are compared under uniform and partial shadow irradiation conditions. The first MPPT algorithm is based on the conventional perturbation and observation (P&O) method and the second one uses a differential evolution (DE) optimization technique. It is found that the DE optimization method leads to a higher PV output power than using the P&O method under the partial shadow condition. Hence, the pump flow rate is much higher. However, under a uniform irradiation level, the PV system provides the available maximum power using both MPPT techniques. The experimental measurements are obtained to validate the theoretical work
An ultra-fast digital diffuse optical spectroscopic imaging system for neoadjuvant chemotherapy monitoring
Up to 20% of breast cancer patients who undergo presurgical (neoadjuvant) chemotherapy have no response to treatment. Standard-of-care imaging modalities, including MRI, CT, mammography, and ultrasound, measure anatomical features and tumor size that reveal response only after months of treatment. Recently, non-invasive, near-infrared optical markers have shown promise in indicating the efficacy of treatment at the outset of the chemotherapy treatment. For example, frequency domain Diffuse Optical Spectroscopic Imaging (DOSI) can be used to characterize the optical scattering and absorption properties of thick tissue, including breast tumors. These parameters can then be used to calculate tissue concentrations of chromophores, including oxyhemoglobin, deoxyhemoglobin, water, and lipids. Tumors differ in hemoglobin concentration, as compared with healthy background tissue, and changes in hemoglobin concentration during neoadjuvant chemotherapy have been shown to correlate with efficacy of treatment. Using DOSI early in treatment to measure chromophore concentrations may be a powerful tool for guiding neoadjuvant chemotherapy treatment.
Previous frequency-domain DOSI systems have been limited by large device footprints, complex electronics, high costs, and slow acquisition speeds, all of which complicate access to patients in the clinical setting. In this work a new digital DOSI (dDOSI) system has been developed, which is relatively inexpensive and compact, allowing for use at the bedside, while providing unprecedented measurement speeds. The system builds on, and significantly advances, previous dDOSI setups developed by our group and, for the first time, utilizes hardware-integrated custom board-level direct digital synthesizers (DDS) and analog to digital converters (ADC) to generate and directly measure signals utilizing undersampling techniques. The dDOSI system takes high-speed optical measurements by utilizing wavelength multiplexing while sweeping through hundreds of modulation frequencies in tens of milliseconds. The new dDOSI system is fast, inexpensive, and compact without compromising accuracy and precision
Envelope amplifier based on switching capacitors for high efficiency RF amplifiers
Modern transmitters usually have to amplify and transmit signals with simultaneous envelope and phase modulation. Due to this property of the transmitted signal, linear power amplifiers (class A, B, or AB) are usually used as a solution for the power amplifier stage. These amplifiers have high linearity, but suffer from low efficiency when the transmitted signal has high peak-to-average power ratio. The Kahn envelope elimination and restoration technique is used to enhance the efficiency of RF transmitters, by combining highly efficient, nonlinear RF amplifier (class E) with a highly efficient envelope amplifier in order to obtain a linear and highly efficient RF amplifier. This paper presents a solution for the envelope amplifier based on a multilevel converter in series with a linear regulator. The multilevel converter is implemented by employing voltage dividers based on switching capacitors. The implemented envelope amplifier can reproduce any signal with a maximum spectral component of 2 MHz and give instantaneous maximum power of 50 W. The efficiency measurements show that when the signals with low average value are transmitted, the implemented prototypes have up to 20% higher efficiency than linear regulators used as a conventional solution
A closed-loop digitally controlled MEMS gyroscope with unconstrained Sigma-Delta force-feedback
In this paper, we describe the system architecture and prototype measurements of a MEMS gyroscope system with a resolution of 0.025 degrees/s/root Hz. The architecture makes extensive use of control loops, which are mostly in the digital domain. For the primary mode both the amplitude and the resonance frequency are tracked and controlled. The secondary mode readout is based on unconstrained Sigma Delta force-feedback, which does not require a compensation filter in the loop and thus allows more beneficial quantization noise shaping than prior designs of the same order. Due to the force-feedback, the gyroscope has ample dynamic range to correct the quadrature error in the digital domain. The largely digital setup also gives a lot of flexibility in characterization and testing, where system identification techniques have been used to characterize the sensors. This way, a parasitic direct electrical coupling between actuation and readout of the mass-spring systems was estimated and corrected in the digital domain. Special care is also given to the capacitive readout circuit, which operates in continuous time
Amplificadores de potência para radiofrequência insensíveis à impedância de carga
Solid state power amplifiers (SSPAs) evolved significantly over the last few
decades, mainly, due to the use of new transistor technologies, such as
gallium nitride (GaN) high-electron-mobility transistors (HEMTs), very advanced
computer-aided design (CAD) software, and very effective digital
pre-distortion (DPD) algorithms. This led to a considerable performance
improvement, in terms of energy efficiency, output power, and linearity. To
achieve this performance, power amplifier (PA) designers normally push the
used transistors very close to their physical safe operating limits, and consider
them to operate for a fixed output load. However, the designed PAs are
used for many different industrial and/or telecommunication applications,
and, in some cases, such as, for example, microwave cooking or massive
multiple-input multiple-output (MIMO) fifth generation (5G) base stations
(BSs), the output load of these amplifiers can change. Under this nonoptimal
scenario, the used transistors will operate for non-nominal loads,
and the PAs performance can be severely degraded. Moreover, in highly
optimized designs, where the transistors are operated close to their safe
limits, their reliability can be reduced or, in extreme cases, they can even be
permanently damaged. Therefore, load insensitive PA architectures, and/or
techniques that aim at reducing the load variation seen by the PA, are necessary
to improve the performance under load varying scenarios. This thesis
presents various strategies to improve load insensitiveness of PAs. The presented
techniques are based on tunable matching networks (TMNs) and on
the amplifiers’ drain supply voltage (VDS) variation. The developed TMNs
successfully reduced the load variation seen by the PA, and its performance
was greatly improved, for non-optimal loading, by also using the derived load
dependent VDS variation. These different approaches were tested and validated
on single-ended PAs and then, based on their advantages and disadvantages,
the most promising technique – the supply voltage modulation –
was selected for the design of a Doherty power amplifier (DPA), which is of
paramount importance for telecommunication applications. Moreover, since
in some applications the output load variation can be unpredictable, we also
developed a complete quasi-load insensitive (QLI) PA system that includes
an impedance tracking circuit and an automatic real-time compensation of
the amplifier performance.Os amplificadores de potência de estado sólido (SSPAs) evoluíram significativamente
nas últimas décadas, principalmente devido à utilização de
novas tecnologias de transístores, como os transístores de alta mobilidade
(HEMTs) de nitreto de gálio (GaN), de ferramentas muito avançadas de
projeto assistido por computador (CAD) e de algoritmos de pré-distorção
digital (DPD) muito evoluídos. Isto levou a uma melhoria de desempenho
considerável, em termos de eficiência energética, potência de saída e linearidade.
Normalmente, para obter estes níveis de desempenho, os engenheiros
projetam os amplificadores permitindo que os transístores utilizados operem
muito perto do seu limite físico de funcionamento seguro e considerando
que vão operar para uma carga fixa. No entanto, os amplificadores projetados
são utilizados em diversas aplicações industriais e/ou telecomunicações
e, em alguns casos, como por exemplo fornos micro-ondas ou estações base
5G, a sua carga de saída pode variar devido a várias causas, que podem
ser previsíveis ou imprevisíveis. Neste cenário não ideal, os transístores utilizados
operam para cargas não ótimas e o desempenho dos amplificadores
pode ser muito degradado. Além disso, em projetos muito otimizados, onde
os transístores são operados perto do seu limite de funcionamento seguro,
a sua durabilidade pode ser reduzida ou, em casos extremos, podem até
ser permanentemente danificados. Portanto, para melhorar o desempenho
dos amplificadores em cenários de carga variável, são necessárias novas arquiteturas
e/ou técnicas que visam reduzir a variação da carga vista pelos
transístores utilizados. Esta tese apresenta várias estratégias para melhorar
a insensibilidade dos amplificadores em relação à variação de carga.
As técnicas apresentadas são baseadas em malhas de adaptação dinâmicas
(TMNs) e na variação da tensão de alimentação dos amplificadores. As
malhas de adaptação desenvolvidas permitiram reduzir a variação de carga
vista pelo amplificador e a variação da sua tensão de alimentação permitiu
melhorar o desempenho para operação com cargas não ótimas. Estas
abordagens foram testadas e validadas em amplificadores baseados num só
transístor, e, posteriormente, com base nas suas vantagens e desvantagens,
a técnica mais promissora – a modulação da tensão de alimentação – foi
selecionada para o projeto de um amplificador Doherty, que é imprescindível
para telecomunicações. Além disso, como em algumas aplicações a variação
da carga de saída pode ser imprevisível, também desenvolvemos um sistema
completo que inclui um circuito de medida de impedância e compensação
do desempenho do amplificador em tempo real.Programa Doutoral em Engenharia Eletrotécnic
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