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

Dynamically Controllable Integrated Radiation and Self-Correcting Power Generation in mm-Wave Circuits and Systems

This thesis presents novel design methodologies for integrated radiators and power generation at mm-wave frequencies that are enabled by the continued integration of various electronic and electromagnetic (EM) structures onto the same substrate. Beginning with the observation that transistors and their connections to EM radiating structures on an integrated substrate are essentially free, the concept of multi-port driven (MPD) radiators is introduced, which opens a vast design space that has been generally ignored due to the cost structure associated with discrete components that favors fewer transistors connected to antennas through a single port. From Maxwell's equations, a new antenna architecture, the radial MPD antennas based on the concept of MPD radiators, is analyzed to gain intuition as to the important design parameters that explain the wide-band nature of the antenna itself. The radiator is then designed and implemented at 160 GHz in a 0.13 um SiGe BiCMOS process, and the single element design has a measured effective isotropic radiated power (EIRP) of +4.6 dBm with a total radiated power of 0.63 mW. Next, the radial MPD radiator is adapted to enable dynamic polarization control (DPC). A DPC antenna is capable of controlling its radiated polarization dynamically, and entirely electronically, with no mechanical reconfiguration required. This can be done by having multiple antennas with different polarizations, or within a single antenna that has multiple drive points, as in the case of the MPD radiator with DPC. This radiator changes its polarization by adjusting the relative phase and amplitude of its multiple ports to produce polarizations with any polarization angle, and a wide range of axial ratios. A 2x1 MPD radiator array with DPC at 105 GHz is presented whose measurements show control of the polarization angle throughout the entire 0 degree through 180 degree range while in the linear polarization mode and maintaining axial ratios above 10 dB in all cases. Control of the axial ratio is also demonstrated with a measured range from 2.4 dB through 14 dB, while maintaining a fixed polarization angle. The radiator itself has a measured maximum EIRP of +7.8 dBm, with a total radiated power of 0.9 mW, and is capable of beam steering. MPD radiators were also applied in the domain of integrated silicon photonics. For these designs, the driver transistor circuitry was replaced with silicon optical waveguides and photodiodes to produce a 350 GHz signal. Three of these optical MPD radiator designs have been implemented as 2x2 arrays at 350 GHz. The first is a beam forming array that has a simulated gain of 12.1 dBi with a simulated EIRP of -2 dBm. The second has the same simulated performance, but includes optical phase modulators that enable two-dimensional beam steering. Finally, a third design incorporates multi-antenna DPC by combining the outputs of both left and right handed circularly polarized MPD antennas to produce a linear polarization with controllable polarization angle, and has a simulated gain of 11.9 dBi and EIRP of -3 dBm. In simulation, it can tune the polarization from 0 degrees through 180 degrees while maintaining a radiated power that has a 0.35 dB maximum deviation from the mean. The reliability of mm-wave radiators and power amplifiers was also investigated, and two self-healing systems have been proposed. Self-healing is a global feedback method where integrated sensors detect the performance of the circuit after fabrication and report that data to a digital control algorithm. The algorithm then is capable of setting actuators that can control the performance of the mm-wave circuit and counteract any performance degradation that is observed by the sensors. The first system is for a MPD radiator array with a partially integrated self-healing system. The self-healing MPD radiator senses substrate modes through substrate mode pickup sensors and infers the far-field radiated pattern from those sensors. DC current sensors are also included to determine the DC power consumption of the system. Actuators are implemented in the form of phase and amplitude control of the multiple drive points. The second self-healing system is a fully integrated self-healing power amplifier (PA) at 28 GHz. This system measures the output power, gain and efficiency of the PA using radio frequency (RF) power sensors, DC current sensors and junction temperature sensors. The digital block is synthesized from VHDL code on-chip and it can actuate the output power combining matching network using tunable transmission line stubs, as well as the DC operating point of the amplifying transistors through bias control. Measurements of 20 chips confirm self-healing for two different algorithms for process variation and transistor mismatch, while measurements from 10 chips show healing for load impedance mismatch, and linearity healing. Laser induced partial and total transistor failure show the benefit of self-healing in the case of catastrophic failure, with improvements of up to 3.9 dB over the default case. An exemplary yield specification shows self-healing improving the yield from 0% up through 80%.</p

Optimum power transfer in RF front end systems using adaptive impedance matching technique

Matching the antenna's impedance to the RF-front-end of a wireless communications system is challenging as the impedance varies with its surround environment. Autonomously matching the antenna to the RF-front-end is therefore essential to optimize power transfer and thereby maintain the antenna's radiation efficiency. This paper presents a theoretical technique for automatically tuning an LC impedance matching network that compensates antenna mismatch presented to the RF-front-end. The proposed technique converges to a matching point without the need of complex mathematical modelling of the system comprising of non-linear control elements. Digital circuitry is used to implement the required matching circuit. Reliable convergence is achieved within the tuning range of the LC-network using control-loops that can independently control the LC impedance. An algorithm based on the proposed technique was used to verify its effectiveness with various antenna loads. Mismatch error of the technique is less than 0.2%. The technique enables speedy convergence (&lt;5 s) and is highly accurate for autonomous adaptive antenna matching networks

A Fully-Integrated Reconfigurable Dual-Band Transceiver for Short Range Wireless Communications in 180 nm CMOS

© 2015 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other users, including reprinting/ republishing this material for advertising or promotional purposes, creating new collective works for resale or redistribution to servers or lists, or reuse of any copyrighted components of this work in other works.A fully-integrated reconfigurable dual-band (760-960 MHz and 2.4-2.5 GHz) transceiver (TRX) for short range wireless communications is presented. The TRX consists of two individually-optimized RF front-ends for each band and one shared power-scalable analog baseband. The sub-GHz receiver has achieved the maximum 75 dBc 3rd-order harmonic rejection ratio (HRR3) by inserting a Q-enhanced notch filtering RF amplifier (RFA). In 2.4 GHz band, a single-ended-to-differential RFA with gain/phase imbalance compensation is proposed in the receiver. A ΣΔ fractional-N PLL frequency synthesizer with two switchable Class-C VCOs is employed to provide the LOs. Moreover, the integrated multi-mode PAs achieve the output P1dB (OP1dB) of 16.3 dBm and 14.1 dBm with both 25% PAE for sub-GHz and 2.4 GHz bands, respectively. A power-control loop is proposed to detect the input signal PAPR in real-time and flexibly reconfigure the PA's operation modes to enhance the back-off efficiency. With this proposed technique, the PAE of the sub-GHz PA is improved by x3.24 and x1.41 at 9 dB and 3 dB back-off powers, respectively, and the PAE of the 2.4 GHz PA is improved by x2.17 at 6 dB back-off power. The presented transceiver has achieved comparable or even better performance in terms of noise figure, HRR, OP1dB and power efficiency compared with the state-of-the-art.Peer reviewe

RECONFIGURABLE POWER AMPLIFIER WITH TUNABLE INTERSTAGE MATCHING NETWORK USING GaAs MMIC AND SURFACE-MOUNT TECHNOLOGY

As the demand of reconfigurable devices increases, the possibility of exploiting the interstage matching network in a two-stage amplifier to provide center frequency tuning capability is explored. While placement of tuning elements at the input and/or output matching network has some disadvantages, placement of tuning elements in the interstage absorbs the lossy components characteristics into useful attributes. The circuit design methodology includes graphical method to determine the bandpass topology that achieves high Q-contour on the Smith chart thus result in narrow bandwidth. T-section and π-section topologies are used to match reactive terminations provided by the first and second amplifier stages. The design methodology also includes utilization of interstage mismatch loss that decreases as increasing frequency to compensate for amplifier gain roll-off and equalize the gain at different tuning states. In prototype realization, three design configurations are discussed in this thesis: 1) a discrete design for operation between 0.1 – 0.9 GHz with the total layout area of 7.5 mm x 12.5 mm, 2) a partial monolithic design (Quasi-MMIC) for operation between 0.9 – 2.4 GHz that is 25 times smaller layout area compared to the discrete design, and 3) a conceptual design of integrated monolithic reconfigurable PA for operation between 0.9 – 2.4 GHz that is 130 times smaller layout area compared to the discrete design. One variant of the fabricated reconfigurable PA offers advantage of 4-states center frequency tuning from 1.37 GHz to 1.95 GHz with gain of 21.5 dB (+ 0.7 dB). The feasibility of interstage matching network as tuning elements in reconfigurable power amplifier has been explored. The input and output matching networks are fixed while the interstage impedances are varied using electronic switching (discrete SP4T and GaAs FET switches). The discrete design is suited for the operation at low frequency (fo < 1GHz), while monolithic implementation of the tunable interstage matching network is required for higher frequency operation due to size limitation and parasitic effects. The reconfigurable PA using MMIC tuner was designed at higher frequency to possibly cover GSM, CDMA, Bluetooth, and WiMAX frequency (0.9 – 2.4 GHz)

Adaptive Impedance Matching Circuits Based on Ferroelectric and Semiconductor Varactors.

Tunability, reconfigurability, and adaptability for RF and microwave circuits are highly desirable because they not only enhance the functionality and performance but also reduce the circuit size and cost. This thesis studies impedance matching circuits that adapt themselves based on either transmit power level or operating environment, targeting the realization of high performance intelligent RF front-ends. Specifically, this study is divided into two distinct topics: (a) linear and efficient power amplifiers (PAs) using tunable matching networks (TMNs) that are dynamically controlled according to the instantaneous power level, and (b) adaptive matching systems based on impedance tuning units to automatically compensate the impedance variation of an antenna. The tuning elements used for implementing the adaptive impedance matching circuits include both semiconductor and ferroelectric varactors. To use the intrinsically nonlinear ferroelectric materials in wireless transceivers with stringent linearity requirements, a technique for improving the linearity of the ferroelectric varactors is proposed and implemented. Up to 16 dB improvement on IIP3 is demonstrated. A study of the tradeoff between the quality factor and tuning speed for the linearized varactors is conducted. Subsequently, two specific applications are investigated. First, a PA with a diode-based TMN is designed, fabricated, and tested. The TMN is dynamically controlled according to the instantaneous power level such that not only optimum load is provided but the AM-AM and AM-PM distortions of the PA are reduced, for the first time demonstrating both efficiency enhancement and linearity improvement using TMNs. Measurement results show that a 13% reduction in DC power consumption is achieved under the same linearity constraint. Second, a closed-loop system is proposed for adaptively performing impedance matching to an unknown load. The adaptive matching system is composed of an impedance tuner, an impedance sensor, and peripheral control circuitries. The impedance tuner, consisting of a phase shifter and a variable transformer, is a novel implementation using an all-pass network topology. Design equations for the phase shifter and variable transformer are derived. Compared to stub-based MEMS tuners, the lumped-element based tuner is preferable for cellular frequency bands because of its compact size.Ph.D.Electrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/62241/1/jsfu_1.pd

Triple-Band Concurrent Reconfigurable Matching Network

Reconfigurable Matching Networks (RMN) have found a wide range of applications, such as antenna impedance matching (Antenna Tuning Units -ATU-), the design of reconfigurable power amplifiers, applications in Magnetic Resonance Imaging (MRI), adjustable low noise amplifier design, etc. In this paper, we propose the experimental design and verification of a reconfigurable impedance synthesis network that can simultaneously work in three different bands and is completely independent so that the impedance variations in a frequency band are approximately transparent to the rest. The variable elements used in this paper are varactors. To verify its operation, it is applied to a process of matching a laser modulator in three different frequency bands for C-RAN (Cloud Radio Access Networks) applications. Experimental results demonstrate, as expected, that losses may depend on the state in which they are driven. Consequently, a state that can guarantee a good match could also imply greater losses, leading to a certain trade-off. The application of genetic algorithms in this context points out that it may be convenient to optimize the insertion losses of the complete chain instead of the return losses

A Novel Method for Tuning a Transistor-Based non-Foster Matching Circuit for Electrically Small Wideband Antennas

This dissertation reviews the application of non-Foster circuits for wideband antenna matching, and introduces a novel, rapid means of “tuning” the circuit to accommodate variations in antenna loadings. The tuning is accomplished via the judicious addition of a common transistor.A detailed literature search is provided, and non-Foster circuits are discussed in detail, including the myriad of implementations with focus on tuning. A comparison between different tuning methods is presented. The novel tuning method is evaluated via the normalized determinant function to ensure stability. Evaluations include simulations using commercially available software and experimentation to ensure not only stability but also that noise added by the active circuitry is manageable. Wideband stable operation is confirmed by pairing the tunable non-Foster matching circuit with an electrically small, resistively loaded dipole, and performance gains are demonstrated using the tunability feature. The resistively loaded dipole alone demonstrates reasonable performance at higher frequencies, but performance degrades considerably at lower frequencies, when the dipole is electrically small. The tunable non-Foster circuit is shown to alleviate some of this degradation. Additionally, applications other than wideband antenna matching can benefit from tunable non-Foster circuits such as tunable filters and phase shifters, and these are discussed as well. Finally, practical limitations of non-Foster circuits are presented

ULTRA LOW POWER FSK RECEIVER AND RF ENERGY HARVESTER

This thesis focuses on low power receiver design and energy harvesting techniques as methods for intelligently managing energy usage and energy sources. The goal is to build an inexhaustibly powered communication system that can be widely applied, such as through wireless sensor networks (WSNs). Low power circuit design and smart power management are techniques that are often used to extend the lifetime of such mobile devices. Both methods are utilized here to optimize power usage and sources. RF energy is a promising ambient energy source that is widely available in urban areas and which we investigate in detail. A harvester circuit is modeled and analyzed in detail at low power input. Based on the circuit analysis, a design procedure is given for a narrowband energy harvester. The antenna and harvester co-design methodology improves RF to DC energy conversion efficiency. The strategy of co-design of the antenna and the harvester creates opportunities to optimize the system power conversion efficiency. Previous surveys have found that ambient RF energy is spread broadly over the frequency domain; however, here it is demonstrated that it is theoretically impossible to harvest RF energy over a wide frequency band if the ambient RF energy source(s) are weak, owing to the voltage requirements. It is found that most of the ambient RF energy lies in a series of narrow bands. Two different versions of harvesters have been designed, fabricated, and tested. The simulated and measured results demonstrate a dual-band energy harvester that obtains over 9% efficiency for two different bands (900MHz and 1800MHz) at an input power as low as -19dBm. The DC output voltage of this harvester is over 1V, which can be used to recharge the battery to form an inexhaustibly powered communication system. A new phase locked loop based receiver architecture is developed to avoid the significant conversion losses associated with OOK architectures. This also helps to minimize power consumption. A new low power mixer circuit has also been designed, and a detailed analysis is provided. Based on the mixer, a low power phase locked loop (PLL) based receiver has been designed, fabricated and measured. A power management circuit and a low power transceiver system have also been co-designed to provide a system on chip solution. The low power voltage regulator is designed to handle a variety of battery voltage, environmental temperature, and load conditions. The whole system can work with a battery and an application specific integrated circuit (ASIC) as a sensor node of a WSN network