Design and characterization of downconversion mixers and the on-chip calibration techniques for monolithic direct conversion radio receivers

This thesis consists of eight publications and an overview of the research topic, which is also a summary of the work. The research described in this thesis is focused on the design of downconversion mixers and direct conversion radio receivers for UTRA/FDD WCDMA and GSM standards. The main interest of the work is in the 1-3 GHz frequency range and in the Silicon and Silicon-Germanium BiCMOS technologies. The RF front-end, and especially the mixer, limits the performance of direct conversion architecture. The most stringent problems are involved in the second-order distortion in mixers to which special attention has been given. The work introduces calibration techniques to overcome these problems. Some design considerations for front-end radio receivers are also given through a mixer-centric approach. The work summarizes the design of several downconversion mixers. Three of the implemented mixers are integrated as the downconversion stages of larger direct conversion receiver chips. One is realized together with the LNA as an RF front-end. Also, some stand-alone structures have been characterized. Two of the mixers that are integrated together with whole analog receivers include calibration structures to improve the second-order intermodulation rejection. A theoretical mismatch analysis of the second-order distortion in the mixers is also presented in this thesis. It gives a comprehensive illustration of the second-order distortion in mixers. It also gives the relationships between the dc-offsets and high IIP2. In addition, circuit and layout techniques to improve the LO-to-RF isolation are discussed. The presented work provides insight into how the mixer immunity against the second-order distortion can be improved. The implemented calibration structures show promising performance. On the basis of these results, several methods of detecting the distortion on-chip and the possibilities of integrating the automatic on-chip calibration procedures to produce a repeatable and well-predictable receiver IIP2 are presented.reviewe

Ultra-Low Power Transmitter and Power Management for Internet-of-Things Devices

Two of the most critical components in an Internet-of-Things (IoT) sensing and transmitting node are the power management unit (PMU) and the wireless transmitter (Tx). The desire for longer intervals between battery replacements or a completely self-contained, battery-less operation via energy harvesting transducers and circuits in IoT nodes demands highly efficient integrated circuits. This dissertation addresses the challenge of designing and implementing power management and Tx circuits with ultra-low power consumption to enable such efficient operation. The first part of the dissertation focuses on the study and design of power management circuits for IoT nodes. This opening portion elaborates on two different areas of the power management field: Firstly, a low-complexity, SPICE-based model for general low dropout (LDO) regulators is demonstrated. The model aims to reduce the stress and computation times in the final stages of simulation and verification of Systems-on-Chip (SoC), including IoT nodes, that employ large numbers of LDOs. Secondly, the implementation of an efficient PMU for an energy harvesting system based on a thermoelectric generator transducer is discussed. The PMU includes a first-in-its-class LDO with programmable supply noise rejection for localized improvement in the suppression. The second part of the dissertation addresses the challenge of designing an ultra- low power wireless FSK Tx in the 900 MHz ISM band. To reduce the power consumption and boost the Tx energy efficiency, a novel delay cell exploiting current reuse is used in a ring-oscillator employed as the local oscillator generator scheme. In combination with an edge-combiner PA, the Tx showed a measured energy efficiency of 0.2 nJ/bit and a normalized energy efficiency of 3.1 nJ/(bit∙mW) when operating at output power levels up to -10 dBm and data rates of 3 Mbps. To close this dissertation, the implementation of a supply-noise tolerant BiCMOS ring-oscillator is discussed. The combination of a passive, high-pass feedforward path from the supply to critical nodes in the selected delay cell and a low cost LDO allow the oscillator to exhibit power supply noise rejection levels better than –33 dB in experimental results

Silicon Germanium BiCMOS Comparator Designed for Use in An Extreme Environment Analog to Digital Converter

This thesis demonstrates the process of creating a radiation hardened and extreme temperature operating comparator from start to finish in the 90 nm SiGe 9HP process node. This includes the entire design flow from examining comparator topologies, to designing the initial comparator circuits, to simulating the comparator over a temperature range of -196°C to 125°C, and finally the testing of the fabricated circuit. To verify the circuit would work at low temperatures, several new device models were created that could be used for simulations at -196°C. In addition to its properties as a standalone comparator, the circuit was also used as a building block in a SAR ADC that would be used for extreme environments

Low-noise amplifiers for integrated multi-mode direct-conversion receivers

The evolution of wireless telecommunication systems during the last decade has been rapid. During this time the design driver has shifted towards fast data applications instead of speech. In addition, the different systems may have a limited coverage, for example, limited to urban areas only. Thus, it has become important for a mobile terminal to be able to use different wireless systems, depending on the application chosen and the location of the terminal. The choice of receiver architecture affects the performance, size, and cost of the receiver. The superheterodyne receiver has hitherto been the dominant radio architecture, because of its good sensitivity and selectivity. However, superheterodyne receivers require expensive filters, which, with the existing technologies, cannot be integrated on the same chip as the receiver. Therefore, architectures using a minimum number of external components, such as direct conversion, have become popular. In addition, compared to the superheterodyne architecture, the direct-conversion architecture has benefits when multi-mode receivers, which are described in this thesis, are being designed. In this thesis, the limitations placed on the analog receiver by different system specifications are introduced. The estimations for the LNA specifications are derived from these specifications. In addition, the limitations imposed by different types of receiver architectures are described. The inductively-degenerated LNA is the basis for all the experimental circuits. The different components for this configuration are analyzed and compared to other commonly-used configurations in order to justify the use of an inductively-degenerated LNA. Furthermore, the design issues concerning the LNA-mixer interface in direct-conversion receivers are analyzed. Without knowing these limitations, it becomes difficult to understand the choices made in the experimental circuits. One of the key parts of this thesis describes the design and implementation of a single-chip multi-mode LNA, which is one of the key blocks in multi-mode receivers. The multi-mode structures in this thesis were developed for a direct-conversion receiver where only one system is activated at a time. The LNA interfaces to a pre-select filter and mixers and the different LNA components are analyzed in detail. Furthermore, the design issues related to possible interference from additional systems on single-chip receivers are analyzed and demonstrated. A typical receiver includes variable gain, which can be implemented both in the analog baseband and/or in the RF. If the variable gain is implemented in the RF parts, it is typically placed in the LNA or in a separate gain control stage. Several methods that can be used to implement a variable gain in the LNA are introduced and compared to each other. Furthermore, several of these methods are included in the experimental circuits. The last part of this thesis concentrates on four experimental circuits, which are described in this thesis. The first two chips describe an RF front-end and a direct-conversion receiver for WCDMA applications. The whole receiver demonstrates that it is possible to implement A/D converters on the same chip as sensitive RF blocks without significantly degrading receiver performance. The other two chips describe an RF front-end for WCDMA and GSM900 applications and a direct-conversion receiver for GSM900, DCS1800, PCS1900 and WCDMA systems. These ICs demonstrate the usability of the circuit structure developed and presented in this thesis. The chip area in the last multi-mode receiver is not significantly increased compared to corresponding single-system receivers.reviewe

A 200-MHz fully-differential CMOS front-end with an on-chip inductor for magnetic resonance imaging

Recently, there is a growing interest in applying electronic circuit design for biomedical applications, especially in the area of nuclear magnetic resonance (NMR). NMR has been used for many years as a spectroscopy technique for analytical chem- istry. Previous studies have demonstrated the design and fabrication of planar spiral inductors (microcoils) that serve as detectors for nuclear magnetic resonance mi- crospectroscopy. The goal of this research was to analyze, design, and test a prototype integrated sensor, which consisted of a similar microcoil detector with analog components to form a multiple-channel front-end for a magnetic resonance imaging (MRI) system to perform microspectroscopy. The research has succeeded in producing good function- ality for a multiple-channel sensor. The sensor met expectations compared to similar one-channel systems through experiments in channel separation and good signal-to- noise ratios

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

Mixed-source charger-supply CMOS IC

The proposed research objective is to develop, test, and evaluate a mixer and charger-supply CMOS IC that derives and mixes energy and power from mixed sources to accurately supply a miniaturized system. Since the energy-dense source stores more energy than the power-dense source while the latter supplies more power than the former, the proposed research aims to develop an IC that automatically selects how much and from which source to draw power to maximize lifetime per unit volume. Today, the state of the art lacks the intelligence and capability to select the most appropriate source from which to extract power to supply the time-varying needs of a small system. As such, the underlying objective and benefit of this research is to reduce the size of a complete electronic system so that wireless sensors and biomedical implants, for example, as a whole, perform well, operate for extended periods, and integrate into tiny spaces.Ph.D

System-level design and RF front-end implementation for a 3-10ghz multiband-ofdm ultrawideband receiver and built-in testing techniques for analog and rf integrated circuits

This work consists of two main parts: a) Design of a 3-10GHz UltraWideBand (UWB) Receiver and b) Built-In Testing Techniques (BIT) for Analog and RF circuits. The MultiBand OFDM (MB-OFDM) proposal for UWB communications has received significant attention for the implementation of very high data rate (up to 480Mb/s) wireless devices. A wideband LNA with a tunable notch filter, a downconversion quadrature mixer, and the overall radio system-level design are proposed for an 11-band 3.4-10.3GHz direct conversion receiver for MB-OFDM UWB implemented in a 0.25mm BiCMOS process. The packaged IC includes an RF front-end with interference rejection at 5.25GHz, a frequency synthesizer generating 11 carrier tones in quadrature with fast hopping, and a linear phase baseband section with 42dB of gain programmability. The receiver IC mounted on a FR-4 substrate provides a maximum gain of 67-78dB and NF of 5-10dB across all bands while consuming 114mA from a 2.5V supply. Two BIT techniques for analog and RF circuits are developed. The goal is to reduce the test cost by reducing the use of analog instrumentation. An integrated frequency response characterization system with a digital interface is proposed to test the magnitude and phase responses at different nodes of an analog circuit. A complete prototype in CMOS 0.35mm technology employs only 0.3mm2 of area. Its operation is demonstrated by performing frequency response measurements in a range of 1 to 130MHz on 2 analog filters integrated on the same chip. A very compact CMOS RF RMS Detector and a methodology for its use in the built-in measurement of the gain and 1dB compression point of RF circuits are proposed to address the problem of on-chip testing at RF frequencies. The proposed device generates a DC voltage proportional to the RMS voltage amplitude of an RF signal. A design in CMOS 0.35mm technology presents and input capacitance <15fF and occupies and area of 0.03mm2. The application of these two techniques in combination with a loop-back test architecture significantly enhances the testability of a wireless transceiver system

Design of a low-noise optoelectronic amplifier channel for a laser radar

Abstract. The goal of this Master’s thesis is to find and develop the best topologies and circuit structures for a low-noise amplifier channel for a laser radar application. In this work different topologies, their strengths, weaknesses and challenges are studied. Low-noise optoelectronic amplifier channels have been used extensively in a variety of applications such as wireless communication, optical receivers and laser radar. The common constraint for all the mentioned applications is the noise. The optical input signal for optoelectronic receivers can be very weak. In order to detect the signal reliably and accurately, the receiver must not add significant noise to the input signal. Therefore, this thesis concentrates on improving the signal to noise ratio (SNR) by minimizing the noise sources, filtering the high frequency noise and amplifying the signal. In addition, the delay of the whole channel should be constant with respect to signal strength, supply voltage etc. variations. This low-noise optoelectronic amplifier channel can be employed in a laser radar to detect the distance of several kilometers.Pienikohinaisen optoelektronisen vahvistinkanavan suunnittelu lasertutkasovellukseen. Tiivistelmä. Tämän diplomityön tavoitteena on etsiä ja kehittää sopivia piiriratkaisuja ja -rakenteita lasertutkan pienikohinaiseen vahvistinkanavaan. Työssä tutkittiin eri rakenteita, niiden vahvuuksia, heikkouksia ja haasteita. Pienikohinaisia optoelektronisia vahvistinkanavia on käytetty paljon useissa sovelluksissa kuten langattomassa viestinnässä, optisissa vastaanottimissa ja lasertutkissa. Näissä sovelluksissa yhteisenä haasteena on kohina. Optoelektronisen vastaanottimen tulosignaali voi olla hyvin heikko, joten tarkan ja luotettavan vastaanoton varmistamiseksi vastaanottimen itsessään tulee olla hyvin pienikohinainen. Tässä työssä keskityttiinkin signaalikohinasuhteen (SNR) optimointiin minimoimalla itse kohinalähteet, suodattamalla korkeataajuista kohinaa ja vahvistamalla signaalia. Lisäksi koko kanavan viive oli pidettävä mahdollisimman vakiona eri signaalitasoilla, eri lämpötiloissa, eri käyttöjännitteillä jne. Työssä kehitettyä optoelektronista vahvistinkanavaa voidaan käyttää lasertutkissa mittaamaan etäisyyksiä kilometrien päässä oleviin kohteisiin

Analog-to-digital interface design in wireless receivers

As one of the major building blocks in a wireless receiver, the Analog-to-Digital Interface (ADI) provides link and transition between the analog Radio Frequency (RF) frontend and the baseband Digital Signal Processing (DSP) module. The rapid development of the radio technologies raises new design challenges for the receiver ADI implementation. Requirements, such as power consumption optimization, multi-standard compatibility, fast settling capability and wide signal bandwidth capacity, are often encountered in a low voltage ADI design environment. Previous research offers ADI design schemes that emphasize individual merit. A systematic ADI design methodology is, however, not suffciently studied. In this work, the ADI design for two receiver systems are employed as research vehicles to provide solutions for different ADI design issues. A zero-crossing demodulator ADI is designed in the 0.35µm CMOS technology for the Bluetooth receiver to provide fast settling. Architectural level modi&#64257;cation improves the process variation and the Local Oscillation (LO) frequency offset immunity of the demodulator. A 16.2dB Signal-to-Noise Ratio (SNR) at 0.1% Bit Error Rate (BER) is achieved with less than 9mW power dissipation in the lab measurement. For ADI in the 802.11b/Bluetooth dual-mode receiver, a con&#64257;gurable time-interleaved pipeline Analog-to-Digital-Converter (ADC) structure is adopted to provide the required multi-standard compatibility. An online digital calibration scheme is also proposed to compensate process variation and mismatching. The prototype chip is fabricated in the 0.25µm BiCMOS technology. Experimentally, an SNR of 60dB and 64dB are obtained under the 802.11b and Bluetooth receiving modes, respectively. The power consumption of the ADI is 20.2mW under the 802.11b receiving mode and 14.8mW under the Bluetooth mode. In this dissertation, each step of the receiver ADI design procedure, from system level optimization to the transistor level implementation and lab measurement, is illustrated in detail. The observations are carefully studied to provide insight on receiver ADI design issues. The ADI design for the Ultra-Wide Band (UWB) receiver is also studied at system level. Potential ADI structure is proposed to satisfy the wide signal bandwidth and high speed requirement for future applications