CMOS Data Converters for Closed-Loop mmWave Transmitters

With the increased amount of data consumed in mobile communication systems, new solutions for the infrastructure are needed. Massive multiple input multiple output (MIMO) is seen as a key enabler for providing this increased capacity. With the use of a large number of transmitters, the cost of each transmitter must be low. Closed-loop transmitters, featuring high-speed data converters is a promising option for achieving this reduced unit cost.In this thesis, both digital-to-analog (D/A) and analog-to-digital (A/D) converters suitable for wideband operation in millimeter wave (mmWave) massive MIMO transmitters are demonstrated. A 2 76 bit radio frequency digital-to-analog converter (RF-DAC)-based in-phase quadrature (IQ) modulator is demonstrated as a compact building block, that to a large extent realizes the transmit path in a closed-loop mmWave transmitter. The evaluation of an successive-approximation register (SAR) analog-to-digital converter (ADC) is also presented in this thesis. Methods for connecting simulated and measured performance has been studied in order to achieve a better understanding about the alternating comparator topology.These contributions show great potential for enabling closed-loop mmWave transmitters for massive MIMO transmitter realizations

Wideband CMOS Data Converters for Linear and Efficient mmWave Transmitters

With continuously increasing demands for wireless connectivity, higher\ua0carrier frequencies and wider bandwidths are explored. To overcome a limited transmit power at these higher carrier frequencies, multiple\ua0input multiple output (MIMO) systems, with a large number of transmitters\ua0and antennas, are used to direct the transmitted power towards\ua0the user. With a large transmitter count, each individual transmitter\ua0needs to be small and allow for tight integration with digital circuits. In\ua0addition, modern communication standards require linear transmitters,\ua0making linearity an important factor in the transmitter design.In this thesis, radio frequency digital-to-analog converter (RF-DAC)-based transmitters are explored. They shift the transition from digital\ua0to analog closer to the antennas, performing both digital-to-analog\ua0conversion and up-conversion in a single block. To reduce the need for\ua0computationally costly digital predistortion (DPD), a linear and wellbehaved\ua0RF-DAC transfer characteristic is desirable. The combination\ua0of non-overlapping local oscillator (LO) signals and an expanding segmented\ua0non-linear RF-DAC scaling is evaluated as a way to linearize\ua0the transmitter. This linearization concept has been studied both for\ua0the linearization of the RF-DAC itself and for the joint linearization of\ua0the cascaded RF-DAC-based modulator and power amplifier (PA) combination.\ua0To adapt the linearization, observation receivers are needed.\ua0In these, high-speed analog-to-digital converters (ADCs) have a central\ua0role. A high-speed ADC has been designed and evaluated to understand\ua0how concepts used to increase the sample rate affect the dynamic performance

Digital PLL for ISM applications

In modern transceivers, a low power PLL is a key block. It is known that with the evolution of technology, lower power and high performance circuitry is a challenging demand. In this thesis, a low power PLL is developed in order not to exceed 2mW of total power consumption. It is composed by small area blocks which is one of the main demands. The blocks that compose the PLL are widely abridged and the final solution is shown, showing why it is employed. The VCO block is a Current-Starved Ring Oscillator with a frequency range from 400MHz to 1.5GHz, with a 300μW to approximately 660μW power consumption. The divider is composed by six TSPC D Flip-Flop in series, forming a divide-by-64 divider. The Phase-Detector is a Dual D Flip-Flop detector with a charge pump. The PLL has less than a 2us lock time and presents a output oscillation of 1GHz, as expected. It also has a total power consumption of 1.3mW, therefore fulfilling all the specifications. The main contributions of this thesis are that this PLL can be applied in ISM applications due to its covering frequency range and low cost 130nm CMOS technology

Integration of broadband direct-conversion quadrature modulators

To increase spectral efficiency, transmitters usually send only one of the information carrying sidebands centered around a single radio-frequency carrier. The close-lying mirror, or image, sideband will be eliminated either by the filtering method or by the phasing method. Since filter Q-values rise in direct relation to the transmitted frequencies, the filtering method is generally not feasible for integrated microwave transmitters. A quadrature modulator realizes the phasing method by combining signals phased at quadrature (i.e. at 90° offsets) to produce a single-sideband (SSB) output. In this way output filtering can be removed or its specifications greatly relieved so as to produce an economical microwave transmitter. The proliferation of integrated circuit (IC) technologies since the 1980s has further boosted the popularity of quadrature modulator as an IC realization makes possible the economical production of two closely matched doubly balanced mixers, which suppress carrier and even-order spurious leakage to circuit output. Another strength of IC is its ability to perform microwave quadrature generation accurately on-chip, and thereby to avoid most of the interconnect parasitics which could ruin high-frequency quadrature signaling. Nevertheless, all quadrature modulator implementations are sensitive to phasing and amplitude errors, which are born as a result of mismatches, from the use of inaccurate differential signaling, and from inadequacies in the phasing circuitry itself. A 2° phase error is easily produced, and it reduces the image-rejection ratio (IRR) to −30 dBc. Therefore, as baseband signals synthesized by digital signal processing (DSP) are sufficiently accurate, this thesis concentrates on analyzing and producing the microwave signal path of a direct-conversion quadrature modulator with special emphasis on broadband, multimode radio-compatible operation. A model of the direct-conversion quadrature modulator operation has been developed, which reveals the effect the circuit non-linearities and mismatch-related offsets have on available performance. Further, theoretical proof is given of the well-known property of improving differential signal balance that cascaded differential pairs exhibit. Among the practical results, a current reuse mixer has been developed, which improves the transmitted signal-to-noise-ratio (SNR) by 3 dB, with a maximum measured dynamic range of +158 dB. The complementary bipolar process was further used to extend the bipolar push-pull stage bandwidth to 9.5 GHz. At the core of this work is the parallel switchable polyphase (PP) filter quadrature generator that was developed, since it makes possible accurate broadband IQ generation without the high loss that usually results from the application of PP filtering. Two IQ modulator prototypes were realized to test simulated and theoretically derived data: the 0.8 µm SiGe IC achieves an IRR better than −40 dBc over 0.75-3.6 GHz, while the 0.13 µm digital bulk CMOS IC achieves better than −37 dBc over 0.56-4.76 GHz. For this IRR performance the SiGe prototype boasts the inexpensive solution of integrated baluns, while the CMOS one utilizes a coil-transmission line hybrid transformer at its LO input to drive the switchable PP filters.Taajuuksien käytön tehostamiseksi lähettimet lähettävät yleensä vain toisen informaatiota sisältävistä sivukaistoistaan yhdelle radiotaajuuksiselle kantoaallolle keskitettynä. Viereinen peilitaajuus eli sivukaista vaimennetaan joko suodattamalla tai vaiheistamalla signalointia sopivasti. Koska suodattimen hyvyysluvut nousevat suorassa suhteessa käytettyyn taajuuteen, ei suodatusmenetelmä ole yleensä mahdollinen mikroaaltotaajuusalueen lähettimissä. Kvadratuurimodulaattori toteuttaa vaiheistusmenetelmän yhdistämällä 90-asteen vaihesiirroksin vaiheistetut signaalit yksisivukaistaisen lähetteen tuottamiseksi. Näin voidaan korvata lähdön suodatus joko kokonaan tai lieventämällä vaadittavia suoritusarvoja, jolloin mikroaaltoalueen lähetin voidaan tuottaa taloudellisesti. Integroitujen piiriratkaisujen yleistyminen 1980-luvulta lähtien on edesauttanut kvadratuurimodulaattorin suosiota, koska integroidulle piirille voidaan taloudellisesti tuottaa kaksi hyvin ominaisuuksiltaan toisiaan vastaavaa kaksoisbalansoitua sekoitinta, ja nämä tunnetusti vaimentavat kantoaaltovuotoa ja parillisia harmoonisia piirin lähdössä. Toinen integroitujen piirien vahvuus on kyky tarkkaan mikroaaltoalueen kvadratuurisignalointiin samalla piirillä, jolloin vältetään suurin osa kytkentöjen parasiittisista jotka muutoin voisivat tuhota korkeataajuuksisen 90-asteen vaiheistuksen. Kaikki kvadratuurimodulaattorit ovat joka tapauksessa herkkiä vaiheistus- ja amplitudieroille, joita syntyy komponenttiarvojen satunnaishajonnasta, epätarkan differentiaalisen signaloinnin käytöstä, ja itse vaiheistuspiiristön puutteellisuuksista. Kahden asteen vaihevirhe syntyy helposti, ja tällöin sivukaistavaimennus heikkenee -30 dBc:n tasolle. Tämänvuoksi, ja olettaen että digitaalisella signaaliprosessorilla luotu kantataajuuksinen signalointi on riittävän tarkkaa, tämä väitöskirja keskittyy kvadratuurimodulaattorin mikroaaltotaajuuksisen signaalipolun analysointiin ja tuottamiseen painottaen erityisesti laajakaistaista, monisovellusradioiden kanssa yhteensopivaa toimivuutta. Kvadratuurimodulaattorin toimintamallia on kehitetty siten, että mallissa huomioidaan epälineaarisuuksien ja piirielementtien satunnaishajontojen vaikutus saavutettavalle suorituskyvylle. Lisäksi on teoreettisesti todistettu sinänsä hyvin tunnettu peräkkäin kytkettyjen vahvistinasteiden differentiaalisen signaloinnin symmetrisyyttä parantava vaikutus. Käytännön tuloksista voidaan mainita kehitetty virtaakierrättävä sekoitin, joka parantaa signaali-kohinasuhdetta +3 dB, suurimman mitatun dynaamisen alueen ollessa +158 dB. Samaa komplementaarista bipolaariprosessia käytettiin edelleen bipolaarisen vuorovaihe-asteen kaistan levittämisessä 9.5 GHz:iin. Yhtenä tämän työn tärkeimmistä tuloksista on kehitetty kytkimin valittavista rinnakkaisista monivaihesuodattimista koostuva kvadratuurigeneraattori, jolla on mahdollista tuottaa laajakaistaista IQ-signalointia ilman suurta häviötä joka yleensä liittyy monivaihesuodattimien käyttöön. Kaksi IQ-modulaattoriprototyyppiä toteutettiin simuloitujen ja teoreettisesti mallinnettujen tulosten testaamiseksi: 0.8 µm SiGe integroitu piiri saavuttaa paremman sivukaistavaimennuksen kuin -40 dBc yli 0.75-3.6 GHz, kun taas 0.13 µm digitaalipiirien tuottamiseen tarkoitetulla CMOS prosessilla toteutettu integroitu piiri saavuttaa paremman sivukaistavaimennuksen kuin -37 dBc taajuusalueella 0.56-4.76 GHz. Näihin sivukaistavaimennuksiin SiGe prototyyppi pääsee edullisesti integroiduin symmetrointimuuntajin, kun taas CMOS piirillä käytetään kela-siirtojohto-tyyppistä yhdistelmämuuntajaa LO-sisääntulossa josta ajetaan erikseen kytkettäviä monivaihesuodattimia.reviewe

Design and Implementation of a Re-Configurable Arbitrary Signal Generator and Radio Frequency Spectrum Analyser

This research is focused on the design, simulation and implementation of a reconfigurable arbitrary signal generator and the design, simulation and implementation of a radio frequency spectrum analyser based on digital signal processing. Until recently, Application Specific Integrated Circuits (ASICs) were used to produce high performance re-configurable function and arbitrary waveform generators with comprehensive modulation capabilities. However, that situation is now changing with the availability of advanced but low cost Field Programmable Gate Arrays (FPGAs), which could be used as an alternative to ASICs in these applications. The availability of high performance FPGA families opens up the opportunity to compete with ASIC solutions at a fraction of the development cost of an ASIC solution. A fast digital signal processing algorithm for digital waveform generation, using primarily but not limited to Direct Digital Synthesis (DDS) technologies, developed and implemented in a field-configurable logic, with control provided by an embedded microprocessor replacing a high cost ASIC design appeared to be a very attractive concept. This research demonstrates that such a concept is feasible in its entirety. A fully functional, low-complexity, low cost, pulse, Gaussian white noise and DDS based function and arbitrary waveform generator, capable of being amplitude, frequency and phase modulated by an internally generated or external modulating signal was implemented in a low-cost FPGA. The FPGA also included the capabilities to perform pulse width modulation and pulse delay modulation on pulse waveforms. Algorithms to up-convert the sampling rate of the external modulating signal using Cascaded Integrator Comb (CIC) filters and using interpolation method were analysed. Both solutions were implemented to compare their hardware complexities. Analysis of generating noise with user-defined distribution is presented. The ability of triggering the generator by an internally generated or an external event to generate a burst of waveforms where the time between the trigger signal and waveform output is fixed was also implemented in the FPGA. Finally, design of interface to a microprocessor to provide control of the versatile waveform generator was also included in the FPGA. This thesis summarises the literature, design considerations, simulation and implementation of the generator design. The second part of the research is focused on radio frequency spectrum analysis based on digital signal processing. Most existing spectrum analysers are analogue in nature and their complexity increases with frequency. Therefore, the possibility of using digital techniques for spectrum analysis was considered. The aim was to come up with digital system architecture for spectrum analysis and to develop and implement the new approach on a suitable digital platform. This thesis analyses the current literature on shifting algorithms to remove spurious responses and highlights its drawbacks. This thesis also analyses existing literature on quadrature receivers and presents novel adaptation of the existing architectures for application in spectrum analysis. A wide band spectrum analyser receiver with compensation for gain and phase imbalances in the Radio Frequency (RF) input range, as well as compensation for gain and phase imbalances within the Intermediate Frequency (IF) pass band complete with Resolution Band Width (RBW) filtering, Video Band Width (VBW) filtering and amplitude detection was implemented in a low cost FPGA. The ability to extract the modulating signal from a frequency or amplitude modulated RF signal was also implemented. The same family of FPGA used in the generator design was chosen to be the digital platform for this design. This research makes arguments for the new architecture and then summarises the literature, design considerations, simulation and implementation of the new digital algorithm for the radio frequency spectrum analyser

Millimeter-Wave Super-Regenerative Receivers for Wireless Communication and Radar

Today’s world is becoming increasingly automated and interconnected with billions of smart devices coming online, leading to a steep rise in energy consumption from small microelectronics. This coincides with an urgent push to transform global energy production to green energies, causing disruptions and energy shortages, and making the case for efficient energy use ever more pressing. Two major areas where high growth is expected are the fields of wireless communication and radar sensors. Millimeter-wave frequency bands are planned for fifth-generation (5G) and sixth-generation (6G) cellular communication standards, as well as automotive frequency-modulated continuous wave (FMCW) radar systems for driving assistance and automation. Fast silicon-based technologies enable these advances by operating at high maximum frequencies, such as the silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) technologies. However, even the fastest transistors suffer from low and energy expensive gains at millimeter-wave frequencies. Rather than incremental improvements in circuit efficiency using conventional approaches, a disruptive revolution for green microelectronics could be enabled by exploring the low-power benefits of the super-regenerative receiver for some applications. The super-regenerative receiver uses a regenerative oscillator circuit to increase the gain by positive feedback, through coupling energy from the output back into the input. Careful bias and control of the circuit enables a very large gain from a small number of transistors and a very low energy dissipation. Thus, the super-regenerative oscillator could be used to replace amplifier circuits in high data rate wireless communication systems, or as active reflectors to increase the range of FMCW radar systems, greatly reducing the power consumption. The work in this thesis presents fundamental scientific research into the topic of energy-efficient millimeter-wave super-regenerative receivers for use in civilian wireless communication and radar applications. This research work covers the theory, analysis, and simulations, all the way up to the proof of concept, hardware realization, and experimental characterization. Analysis and modeling of regenerative oscillator circuits is presented and used to improve the understanding of the circuit operation, as well as design goals according to the specific application needs. Integrated circuits are investigated and characterized as a proof of concept for a high data rate wireless communication system operating between 140–220 GHz, and an automotive radar system operating at 60 GHz. Amplitude and phase regeneration capabilities for complex modulation are investigated, and principles for spectrum characterization are derived. The circuits are designed and fabricated in a 130 nm SiGe HBT technology, combining bipolar and complementary metal-oxide semiconductor (BiCMOS) transistors. To prove the feasibility of the research concepts, the work achieves a wireless communication link at 16 Gbit/s over 20 cm distance with quadrature amplitude modulation (QAM), which is a world record for the highest data rate ever reported in super-regenerative circuits. This was powered by a super-regenerative oscillator circuit operating at 180 GHz and providing 58 dB of gain. Energy efficiency is also considerably high, drawing 8.8 mW of dc power consumption, which corresponds to a highly efficient 0.6 pJ/bit. Packaging and module integration innovations were implemented for the system experiments, and additional broadband circuits were investigated to generate custom quench waveforms to further enhance the data rate. For radar active reflectors, a regenerative gain of 80 dB is achieved at 60 GHz from a single circuit, which is the best in its frequency range, despite a low dc power consumption of 25 mW

Techniques for Wideband All Digital Polar Transmission

abstract: Modern Communication systems are progressively moving towards all-digital transmitters (ADTs) due to their high efficiency and potentially large frequency range. While significant work has been done on individual blocks within the ADT, there are few to no full systems designs at this point in time. The goal of this work is to provide a set of multiple novel block architectures which will allow for greater cohesion between the various ADT blocks. Furthermore, the design of these architectures are expected to focus on the practicalities of system design, such as regulatory compliance, which here to date has largely been neglected by the academic community. Amongst these techniques are a novel upconverted phase modulation, polyphase harmonic cancellation, and process voltage and temperature (PVT) invariant Delta Sigma phase interpolation. It will be shown in this work that the implementation of the aforementioned architectures allows ADTs to be designed with state of the art size, power, and accuracy levels, all while maintaining PVT insensitivity. Due to the significant performance enhancement over previously published works, this work presents the first feasible ADT architecture suitable for widespread commercial deployment.Dissertation/ThesisDoctoral Dissertation Electrical Engineering 201

Wireless Terahertz Communications: Optoelectronic Devices and Signal Processing

Novel THz device concepts and signal processing schemes are introduced and experimentally confirmed. Record-high data rates are achieved with a simple envelope detector at the receiver. Moreover, a THz communication system using an optoelectronic receiver and a photonic local oscillator is shown for the first time, and a new class of devices for THz transmitters and receivers is investigated which enables a monolithic co-integration of THz components with advanced silicon photonic circuits