A 24-GHz SiGe Phased-Array Receiver—LO Phase-Shifting Approach

A local-oscillator phase-shifting approach is introduced to implement a fully integrated 24-GHz phased-array receiver using an SiGe technology. Sixteen phases of the local oscillator are generated in one oscillator core, resulting in a raw beam-forming accuracy of 4 bits. These phases are distributed to all eight receiving paths of the array by a symmetric network. The appropriate phase for each path is selected using high-frequency analog multiplexers. The raw beam-steering resolution of the array is better than 10 [degrees] for a forward-looking angle, while the array spatial selectivity, without any amplitude correction, is better than 20 dB. The overall gain of the array is 61 dB, while the array improves the input signal-to-noise ratio by 9 dB

An Octave-Range, Watt-Level, Fully-Integrated CMOS Switching Power Mixer Array for Linearization and Back-Off-Efficiency Improvement

The power mixer array is presented as a novel power generation approach for non-constant envelope signals. It comprises several power mixer units that are dynamically turned on and off to improve the linearity and back-off efficiency. At the circuit level, the power mixer unit can operate as a switching amplifier to achieve high peak power efficiency. Additional circuit level linearization and back-off efficiency improvement techniques are also proposed. To demonstrate the feasibility of this idea, a fully-integrated octave-range CMOS power mixer array is implemented in a 130 nm CMOS process. It is operational between 1.2 GHz and 2.4 GHz and can generate an output power of +31.3 dBm into an external 50 Ω load with a PAE of 42% and a gain compression of only 0.4 dB at 1.8 GHz. It achieves a PAE of 25%, at an average output power of +26.4 dBm, and an EVM of 4.6% with a non-constant-envelope 16 QAM signal. It can also produce arbitrary signal levels down to -70 dBm of output power with the 16 QAM-modulated signal without any RF gain control circuit

A Fully Integrated 24-GHz Eight-Element Phased-Array Receiver in Silicon

This paper reports the first fully integrated 24-GHz eight-element phased-array receiver in a SiGe BiCMOS technology. The receiver utilizes a heterodyne topology and the signal combining is performed at an IF of 4.8 GHz. The phase-shifting with 4 bits of resolution is realized at the LO port of the first down-conversion mixer. A ring LC voltage-controlled oscillator (VCO) generates 16 different phases of the LO. An integrated 19.2-GHz frequency synthesizer locks the VCO frequency to a 75-MHz external reference. Each signal path achieves a gain of 43 dB, a noise figure of 7.4 dB, and an IIP3 of -11 dBm. The eight-path array achieves an array gain of 61 dB and a peak-to-null ratio of 20 dB and improves the signal-to-noise ratio at the output by 9 dB

Low-power CMOS front-ends for wireless personal area networks

The potential of implementing subthreshold radio frequency circuits in deep sub-micron CMOS technology was investigated for developing low-power front-ends for wireless personal area network (WPAN) applications. It was found that the higher transconductance to bias current ratio in weak inversion could be exploited in developing low-power wireless front-ends, if circuit techniques are employed to mitigate the higher device noise in subthreshold region. The first fully integrated subthreshold low noise amplifier was demonstrated in the GHz frequency range requiring only 260 μW of power consumption. Novel subthreshold variable gain stages and down-conversion mixers were developed. A 2.4 GHz receiver, consuming 540 μW of power, was implemented using a new subthreshold mixer by replacing the conventional active low noise amplifier by a series-resonant passive network that provides both input matching and voltage amplification. The first fully monolithic subthreshold CMOS receiver was also implemented with integrated subthreshold quadrature LO (Local Oscillator) chain for 2.4 GHz WPAN applications. Subthreshold operation, passive voltage amplification, and various low-power circuit techniques such as current reuse, stacking, and differential cross coupling were combined to lower the total power consumption to 2.6 mW. Extremely compact resistive feedback CMOS low noise amplifiers were presented as a cost-effective alternative to narrow band LNAs using high-Q inductors. Techniques to improve linearity and reduce power consumption were presented. The combination of high linearity, low noise figure, high broadband gain, extremely small die area and low power consumption made the proposed LNA architecture a compelling choice for many wireless applications.Ph.D.Committee Chair: Laskar, Joy; Committee Member: Chakraborty, Sudipto; Committee Member: Chang, Jae Joon; Committee Member: Divan, Deepakraj; Committee Member: Kornegay, Kevin; Committee Member: Tentzeris, Emmanoui

Design of Low-Power Transmitter and Receiver Front End

This thesis focuses on the design of "RF front-end blocks" for the transmitter and receiver. The blocks include the low noise amplifier (LNA) and mixer downconversion at the receiving side, while the power amplifier includes the pre-driver circuit, and mixer up-conversion at the transmitter side. All of the blocks were designed in a 65nm design kit. The basics of these RF blocks are first described in chapters two to four. After that, the general principle of operations is then described and different topologies are discussed. In chapter 5 the proposed design is discussed. The proposed design is composed of a differential IDCS narrow band LNA, with a passive down-conversion mixer on the receiving side, designed for bluetooth low energy (BLE) applications, that operates at 2.4 GHz with a 1.2 V supply voltage. The overall conversion gain at the receiving side was found to be greater than 13 dB with a double side band noise figure of 8.3 dB having a 1 dB compression point of -11.8 dB, and with IIP3 of -2.06 dBm having a power consumption of 251 μwatts. On the transmission side, a power amplifier with a pre-driver circuit and a passive up-conversion mixer has been designed to operate at a 1.2 V supply at the frequency of operation 2.4 GHz, having overall gain of 24 dB with maximum power added efficiency of 34% when using maximum output power of 11 dBm. The Cadence virtuoso design kit was used for simulation. Additionally, the layout considerations were discussed, followed by presentation of the post-layout results and graphs, and, finally, some conclusions have been drawn

0.5-7.5 GHZ LOW-POWER, INDUCTORLESS CURRENT FOLDED MIXER IN 0.18-μM CMOS FOR BROADBAND APPLICATIONS

A fully differential low-power down-conversion mixer using a TSMC 0.18-μm CMOS process is presented in this paper. The proposed mixer is based on a folded double-balanced Gilbert cell topology that enhances conversion gain and reduces power dissipation. Though, this mixer is designed for 5.8 GHz ISM band applications, but at 0.5-7.5 GHz, the proposed mixer exhibits a maximum conversion gain of 12dB, maximum IIP3 of -2.5 dBm, maximum input 1-dB compression point of -13 dBm, the minimum DSB noise figure of 9.2 dB and a dc power consumption of 2.52 mW at 1.8 V power supply. Also, this circuit architecture increases port-to-port isolations to above 140 dB. Moreover this mixer is suitable for broadband applications

Survey on individual components for a 5 GHz receiver system using 130 nm CMOS technology

La intención de esta tesis es recopilar información desde un punto de vista general sobre los diferentes tipos de componentes utilizados en un receptor de señales a 5 GHz utilizando tecnología CMOS. Se ha realizado una descripción y análisis de cada uno de los componentes que forman el sistema, destacando diferentes tipos de configuraciones, figuras de mérito y otros parámetros. Se muestra una tabla resumen al final de cada sección, comparando algunos diseños que se han ido presentando a lo largo de los años en conferencias internacionales de la IEEE.The intention of this thesis is to gather information from an overview point about the different types of components used in a 5 GHz receiver using CMOS technology. A review of each of the components that form the system has been made, highlighting different types of configurations, figure of merits and parameters. A summary table is shown at the end of each section, comparing many designs that have been presented over the years at international conferences of the IEEE.Departamento de Ingeniería Energética y FluidomecánicaGrado en Ingeniería en Electrónica Industrial y Automátic

Design of RF Receiver Front end Subsystems with Low Noise Amplifier and Active Mixer for Intelligent Transportation Systems Application

This paper presents the design, simulation, and characterization of a novel low-noise amplifier (LNA) and active mixer for intelligent transportation system applications. A low noise amplifier is the key component of RF receiver systems. Design, simulation, and characterization of LNA have been performed to obtain the optimum value of noise figure, gain and reflection coefficient. Proposed LNA achieves measured voltage gains of ~18 dB, reflection coefficients of -20 dB, and noise figures of ~2 dB at 5.9 GHz, respectively. The active mixer is a better choice for a modern receiver system over a passive mixer. Key sight advanced design system in conjunction with the electromagnetic simulation tool, has been to obtain the optimal conversion gain and noise figure of the active mixer. The lower and upper resonant frequencies of mixer have been obtained at 2.45 GHz and 5.25 GHz, respectively. The measured conversion gains at lower and upper frequencies are 12 dB and 10.2 dB, respectively. The measured noise figures at lower and upper frequencies are 5.8 dB and 6.5 dB, respectively. The measured mixer interception point at lower and upper frequencies are 3.9 dBm and 4.2 dBm

Développement d'une architecture innovante de récepteur radar à 77 GHz et démonstration en CMOS 28 nm FDSOI

Grâce à sa capacité à détecter des cibles éloignées malgré une mauvaise visibilité, le radar automobile à 77 GHz joue un rôle important dans l'aide à la conduite. L'utilisation des fréquences millimétriques offre une bonne résolution et une importante capacité d'intégration des circuits. C'est aussi un défi car il faut satisfaire un cahier des charges exigeant sur le bruit et la linéarité du récepteur. Les technologies SiGe BiCMOS ont été les premières utilisées pour la conception de récepteurs radar à 77 GHz. De bons résultats ont été obtenus en se basant sur des architectures utilisant des mélangeurs actifs. Cependant l'utilisation des technologie BiCMOS se traduisait par une consommation élevée, une faible capacité d'intégration et des coûts de production importants. Récemment, l'intégration des procédés CMOS menant à l'augmentation des fréquences de transition rend ces technologies plus attractives pour les applications nécessitant un faible coût et la cointégration de plusieurs fonctions au sein d'une même puce. La littérature sur les récepteurs radars en technologie CMOS à 77 GHz montre que les architectures inspirées par les technologies BiCMOS ne sont pas pertinentes pour cette application. Le but de cette thèse et de montrer que l'utilisation de techniques propres aux technologie CMOS comme l'échantillonnage et l'utilisation de portes logiques permet d'obtenir de très bonnes performances. Dans ce travail, deux nouvelles architectures de récepteurs radars basées sur le principe d'échantillonnage sont proposées. La première architecture est basée sur un mélangeur passif échantillonné qui permet d'obtenir un très bon compromis bruit/linéarité. La seconde exploite les propriétés des mélangeurs sous-échantillonnés afin utiliser une fréquence d'OL trois fois inférieure à la fréquence RF offrant ainsi de très intéressantes simplifications au niveau de la chaîne de distribution du signal d'OL du récepteur. Le contexte de cette étude est expliqué dans le 1er chapitre qui présente les exigences de conception liées à l'application radar et fourni une analyse de l'état de l'art des récepteurs à 77 GHZ. Le chapitre suivant décrit le principe de fonctionnement et l'implémentation d'un mélangeur échantillonné à 77 GHz en technologie CMOS 28- nm FDSOI. Une topologie de mélangeur sous-échantillonné utilisant une fréquence d'OL de 26 GHz pour convertir des signaux RF autour de 77 GHz est ensuite détaillée dans le chapitre 3. Le chapitre 4 conclut cette étude en détaillant l'intégration des mélangeurs étudiés dans les chapitres précédents avec un amplificateur faible bruit dans différents récepteurs radars. Ces architectures de récepteurs basées sur l'échantillonnage sont ensuite comparées entre elles et avec l'état de l'art montrant ainsi leurs avantages et inconvénients. Les résultats de cette comparaison confirment l'intérêt des techniques d'échantillonnage pour la conversion de fréquence dans le cadre de l'application radar.With its ability to detect distant targets under harsh visibility conditions, the 77 GHz automotive radar plays a key role in driving safety. Using mm-wave frequencies allow a good range resolution, a better circuit integration and a wide modulation bandwidth. This is also a challenge for circuit designers who must fulfill stringent requirements especially on the receiver front-end. First 77 GHz radar receivers were manufactured with SiGe BiCMOS processes benefiting from the high transition frequency and high breakdown voltage of Hetero-junction Bipolar Transistors (HBT). Good results have been achieved with active-mixer-based architectures, but these technologies suffer from high power consumptions, limited integration capacity and large production cost. More recently, the scaling down of CMOS processes (coming together with the increase of the transition frequency of the transistors) makes CMOS a good candidate for 77 GHz circuit design, especially when cost target requires single chip solutions. The literature related to CMOS radar receivers highlights that receivers based on BiCMOS architectures generally show poor performances. The aim of this work is to demonstrate that using CMOS specific technics such as sampling and the use of high-speed digital gates should enhance the performance of the receivers. In this work, two innovative radar receiver architectures based on the sampling principle are proposed. The first one shows that this principle can be extended to millimeter wave frequencies to benefit from a very good noise/linearity trade-off. While the second one uses this principle to converts a 77 GHz RF signal by using a 26 GHz LO frequency thus simplifying the LO distribution chain of the receiver. The background of this study is introduced in the chapter 1 presenting the design trade-off related to the 77 GHz radar receiver and provides a review of the existing solutions. The following chapter describes the sampling mixer principle and the implementation of a 77 GHz sampling mixer in 28-nm FDSOI CMOS technology. Then, a sub- sampling mixer topology allowing to convert an RF signal around 77 GHz using a 26 GHz LO frequency is detailed in the chapter 3. The chapter 4 draws the conclusion of this study by showing the implementation of the two proposed sampling-based mixers with a low noise amplifier in 77 GHz front ends. These receiver architectures are compared with the state of the art highlighting the strengths and weaknesses of the proposed solutions. The results of this study demonstrates that using sampling for down conversion can be convenient to address millimeter-wave frequency applications

Simulations of III-V NWFET Double-Balanced Gilbert Cells with an Improved Noise Model

III-V nanowire transistors might provide a mean for extending Moore’s law, by overcoming the scaling limitations ultimately facing planar silicon CMOS. These high frequency capable transistors with cut-off frequencies in the terahertz regime are suitable for radio communication. In this project an active double-balanced gilbert cell mixer consisting of nanowire field-effect transistors (NWFETs) was simulated in Cadence Virtuoso using a compact transistor model. The transistor model was extended to take flicker and thermal noise into account, in order to more accurately compare the mixers against state-of-the-art silicon CMOS implementations. The final mixer for 60 GHz showed much greater linearity (0.4 dBm 1 dB compression and 8.5 dBm IIP 3) than previously reported silicon CMOS counterparts. It exhibited a conversion gain of 3.47 dB, a N F DSB of 14.6 dB and a DC power consumption of 8.7 mW.Based on these findings the design requirements for suitable low noise amplifier was discussed