All-Digital Phase-Locked Loop for Radio Frequency Synthesis

It has been a constant challenge in wireless system design to meet the growing demand for an ever higher data rate and more diversified functionality at minimal cost and power consumption. The key lies in exploiting the phenomenal success of CMOS technology scaling for high-level integration. This underlies the paradigm shift in the field of integrated circuit (IC) design to one that increasingly favours digital circuits as opposed to their analog counterparts. With radio transceiver design for wireless systems in particular, a noticeable trend is the introduction of digital-intensive solutions for traditional analog functions. A prominent example is the emergence of the all-digital phase-locked loop (ADPLL) architectures for frequency synthesis. By avoiding traditional analog blocks, the ADPLL brings the benefits of high-level integration and improved programmability. This thesis presents ADPLL frequency synthesizer design, highlighting practical design considerations and technical innovations. Three prototype designs using a 65-nm CMOS technology are presented. The first example address a low-power ADPLL design for 2.4-GHz ISM (Industrial, Scientific, Medical) band frequency synthesis. A high-speed topology is employed in the implementation for the variable phase accumulator to count full cycles of the radio frequency (RF) output. A simple technique based on a short delay line in the reference signal path allows the time-to-digital converter (TDC) core to operate at a low duty cycle with approximately 95% reduction in its average power consumption. The ADPLL incorporates a two-point modulation scheme with an adaptive gain calibration to allow for direct frequency modulation. The second implementation is a wide-band ADPLL-based frequency synthesizer for cognitive radio sensor units. It employs a digitally controlled ring oscillator with an LC tank introduced to extend the tuning range and reduce power dissipation. An adaptive frequency calibration technique based on binary search is used for fast frequency settling. The third implementation is another wideband ADPLL frequency synthesizer. At the architectural level, separation of coarse-tune and fine-tune branches results in a word length reduction for both of them and allows the coarse tuning logic to be powered off or clock gated during normal operation, which led to a significant reduction in the area and power consumption for the digital logic and simplified the digital design. A dynamic binary search technique was proposed to achieve further improved frequency calibration speed compared with previous techniques. In addition, an original technique was employed for the frequency tuning of the wideband ring oscillator to allow for compact design and excellent linearity

Timing Signals and Radio Frequency Distribution Using Ethernet Networks for High Energy Physics Applications

Timing networks are used around the world in various applications from telecommunications systems to industrial processes, and from radio astronomy to high energy physics. Most timing networks are implemented using proprietary technologies at high operation and maintenance costs. This thesis presents a novel timing network capable of distributed timing with subnanosecond accuracy. The network, developed at CERN and codenamed “White- Rabbit”, uses a non-dedicated Ethernet link to distribute timing and data packets without infringing the sub-nanosecond timing accuracy required for high energy physics applications. The first part of this thesis proposes a new digital circuit capable of measuring time differences between two digital clock signals with sub-picosecond time resolution. The proposed digital circuit measures and compensates for the phase variations between the transmitted and received network clocks required to achieve the sub-nanosecond timing accuracy. Circuit design, implementation and performance verification are reported. The second part of this thesis investigates and proposes a new method to distribute radio frequency (RF) signals over Ethernet networks. The main goal of existing distributed RF schemes, such as Radio-Over-Fibre or Digitised Radio-Over-Fibre, is to increase the bandwidth capacity taking advantage of the higher performance of digital optical links. These schemes tend to employ dedicated and costly technologies, deemed unnecessary for applications with lower bandwidth requirements. This work proposes the distribution of RF signals over the “White-Rabbit” network, to convey phase and frequency information from a reference base node to a large numbers of remote nodes, thus achieving high performance and cost reduction of the timing network. Hence, this thesis reports the design and implementation of a new distributed RF system architecture; analysed and tested using a purpose-built simulation environment, with results used to optimise a new bespoke FPGA implementation. The performance is evaluated through phase-noise spectra, the Allan-Variance, and signalto- noise ratio measurements of the distributed signals

Time and Frequency Transfer in a Coherent Multistatic Radar using a White Rabbit Network

Networks of coherent multistatic radars require accurate and stable time and frequency transfer (TFT) for range and Doppler estimation. TFT techniques based on global navigation satellite systems (GNSS), have been favoured for several reasons, such as enabling node mobility through wireless operation, geospatial referencing, and atomic clock level time and frequency stability. However, such systems are liable to GNSS-denial, where the GNSS carrier is temporarily or permanently removed. A denial-resilient system should consider alternative TFT techniques, such as the White Rabbit (WR) project. WR is an Ethernet based protocol, that is able to synchronise thousands of nodes on a fibre-optic based network with sub-nanosecond accuracy and picoseconds of jitter. This thesis evaluates WR as the TFT network for a coherent multistatic pulse-Doppler radar – NeXtRAD. To test the hypothesis that WR is suitable for TFT in a coherent multistatic radar, the time and frequency performance of a WR network was evaluated under laboratory conditions, comparing the results against a network of multi-channel GPS-disciplined oscillators (GPSDO). A WR-disciplined oscillator (WRDO) is introduced, which has the short-term stability of an ovenised crystal (OCXO), and long-term stability of the WR network. The radar references were measured using a dual mixer time difference technique (DMTD), which allows the phase to be measured with femtosecond level resolution. All references achieved the stringent time and frequency requirements for short-term coherent bistatic operation, however the GPSDOs and WRDOs had the best short-term frequency stability. The GPSDOs had the highest amount of long-term phase drift, with a peak-peak time error of 9.6 ns, whilst the WRDOs were typically stable to within 0.4 ns, but encountered transient phase excursions to 1.5 ns. The TFT networks were then used on the NeXtRAD radar, where a lighthouse, Roman Rock, was used as a static target to evaluate the time and frequency performance of the references on a real system. The results conform well to the laboratory measurements, and therefore, WR can be used for TFT in coherent radar

Recent Trends in Communication Networks

In recent years there has been many developments in communication technology. This has greatly enhanced the computing power of small handheld resource-constrained mobile devices. Different generations of communication technology have evolved. This had led to new research for communication of large volumes of data in different transmission media and the design of different communication protocols. Another direction of research concerns the secure and error-free communication between the sender and receiver despite the risk of the presence of an eavesdropper. For the communication requirement of a huge amount of multimedia streaming data, a lot of research has been carried out in the design of proper overlay networks. The book addresses new research techniques that have evolved to handle these challenges

Architectures and Circuits Leveraging Injection-Locked Oscillators for Ultra-Low Voltage Clock Synthesis and Reference-less Receivers for Dense Chip-to-Chip Communications

High performance computing is critical for the needs of scientific discovery and economic competitiveness. An extreme-scale computing system at 1000x the performance of today’s petaflop machines will exhibit massive parallelism on multiple vertical fronts, from thousands of computational units on a single processor to thousands of processors in a single data center. To facilitate such a massively-parallel extreme-scale computing, a key challenge is power. The challenge is not power associated with base computation but rather the problem of transporting data from one chip to another at high enough rates. This thesis presents architectures and techniques to achieve low power and area footprint while achieving high data rates in a dense very-short reach (VSR) chip-to-chip (C2C) communication network. High-speed serial communication operating at ultra-low supplies improves the energy-efficiency and lowers the power envelop of a system doing an exaflop of loops. One focus area of this thesis is clock synthesis for such energy-efficient interconnect applications operating at high speeds and ultra-low supplies. A sub-integer clockfrequency synthesizer is presented that incorporates a multi-phase injection-locked ring-oscillator-based prescaler for operation at an ultra-low supply voltage of 0.5V, phase-switching based programmable division for sub-integer clock-frequency synthesis, and automatic calibration to ensure injection lock. A record speed of 9GHz has been demonstrated at 0.5V in 45nm SOI CMOS. It consumes 3.5mW of power at 9.12GHz and 0.052 of area, while showing an output phase noise of -100dBc/Hz at 1MHz offset and RMS jitter of 325fs; it achieves a net of -186.5 in a 45-nm SOI CMOS process. This thesis also describes a receiver with a reference-less clocking architecture for high-density VSR-C2C links. This architecture simplifies clock-tree planning in dense extreme-scaling computing environments and has high-bandwidth CDR to enable SSC for suppressing EMI and to mitigate TX jitter requirements. It features clock-less DFE and a high-bandwidth CDR based on master-slave ILOs for phase generation/rotation. The RX is implemented in 14nm CMOS and characterized at 19Gb/s. It is 1.5x faster that previous reference-less embedded-oscillator based designs with greater than 100MHz jitter tolerance bandwidth and recovers error-free data over VSR-C2C channels. It achieves a power-efficiency of 2.9pJ/b while recovering error-free data (BER 200MHz and the INL of the ILO-based phase-rotator (32- Steps/UI) is <1-LSB. Lastly, this thesis develops a time-domain delay-based modeling of injection locking to describe injection-locking phenomena in nonharmonic oscillators. The model is used to predict the locking bandwidth, and the locking dynamics of the locked oscillator. The model predictions are verified against simulations and measurements of a four-stage differential ring oscillator. The model is further used to predict the injection-locking behavior of a single-ended CMOS inverter based ring oscillator, the lock range of a multi-phase injection-locked ring-oscillator-based prescaler, as well as the dynamics of tracking injection phase perturbations in injection-locked masterslave oscillators; demonstrating its versatility in application to any nonharmonic oscillator

Low phase noise 2 GHz Fractional-N CMOS synthesizer IC

Low noise low division 2 GHz RF synthesizer integrated circuits (ICs) are conventionally implemented in some form of HBT process such as SiGe or GaAs. The research in this dissertation differs from convention, with the aim of implementing a synthesizer IC in a more convenient, low-cost Si-based CMOS process. A collection of techniques to push towards the noise and frequency limits of CMOS processes, and possibly other IC processes, is then one of the research outcomes. In a synthesizer low N-divider ratios are important, as high division ratios would amplify in-band phase noise. The design methods deployed as part of this research achieve low division ratios (4 ≤ N ≤ 33) and a high phase comparison frequency (>100 MHz). The synthesizer IC employs a first-order fractional-N topology to achieve increased frequency tuning resolution. The primary N-divider was implemented utilising current mode logic (CML) and the fractional accumulator utilising conventional CMOS. Both a conventional CMOS phase frequency detector (PFD) and a CML PFD were implemented for benchmarking purposes. A custom-built 4.4 GHz synthesizer circuit employing the IC was used to validate the research. In the 4.4 GHz synthesizer circuit, the prototype IC achieved a measured in-band phase noise plateau of L( f ) = -113 dBc/Hz at a 100 kHz frequency offset, which equates to a figure of merit (FOM) of -225 dBc/Hz. The FOM compares well with existing, but expensive, SiGe and GaAs HBT processes. Total IC power dissipation was 710 mW, which is considerably less than commercially available GaAs designs. The complete synthesizer IC was implemented in Austriamicrosystems‟ (AMS) 0.35 μm CMOS process and occupies an area of 3.15 x 2.18 mm2.Dissertation (MEng)--University of Pretoria, 2010.Electrical, Electronic and Computer Engineeringunrestricte

Digital signal processing and digital-to-analog converters for wide-band transmitters

In this thesis, the implementation methods of digital signal processing and digital-to-analog converters for wide-band transmitters are researched. With digital signal processing, the problems of analog signal processing, such as sensitivity to interference and nonidealities of the semiconductor processes, can be avoided. Also, the programmability can be implemented digitally more easily than by means of analog signal processing. During the past few years, wireless communications has evolved from analog to digital, and signal bandwidths have increased, enabling faster and faster data transmission. The evolution of semiconductor processes, decreasing linewidth and supply voltages, has decreased the size of the electronics and power dissipation, enabling the integration of larger and larger systems on single silicon chips. There is little overall benefit in decreasing linewidths to meet the needs of analog design, since it makes the design process more difficult as the device sizes cannot be scaled according to minimum linewidth and because of the decreasing supply voltage. On the other hand, the challenges of digital signal processing are related to the efficient realization of signal processing algorithms in such a way that the required area and power dissipation does not increase extensively. In this book, the problems related to digital filters, upconversion algorithms and digital-to-analog converters used in digital transmitters are researched. Research results are applied to the implementation of a transmitter for a third-generation WCDMA base-station. In addition, the theory of factors affecting the linearity and performance of digital-to-analog converters is researched, and a digital calibration algorithm for enhancement of the static linearity has been presented. The algorithm has been implemented together with a 16-bit converter; its functionality has been demonstrated with measurements.Tässä väitöskirjassa on tutkittu digitaalisen signaalinkäsittelyn toteuttamista ja digitaalisesta analogiseksi -muuntimia laajakaistaisiin lähettimiin. Digitaalisella signaalinkäsittelyllä voidaan välttää monia analogiseen signaalinkäsittelyyn liittyviä ongelmia, kuten häiriöherkkyyttä ja puolijohdeprosessien epäideaalisuuksien vaikutuksia. Myös ohjelmoitavuus on helpommin toteutettavissa digitaalisesti kuin analogisen signaalinkäsittelyn keinoin. Viime vuosina on langattomien tietoliikennejärjestelmien kehitys kulkenut analogisesta digitaaliseen, ja käytettävät signaalikaistanleveydet ovat kasvaneet mahdollistaen yhä nopeamman tiedonsiirron. Puolijohdeprosessien kehitys, kapeneva minimiviivanleveys ja pienemmät käyttöjännitteet, on pienentänyt elektroniikan kokoa ja tehonkulutusta mahdollistaen yhä suurempien kokonaisuuksien integroimisen yhdelle piisirulle. Viivanleveyksien pieneneminen ei kuitenkaan suoraan hyödytä analogiasuunnittelua, jossa piirielementtien kokoa ei välttämättä voida pienentää viivanleveyden pienentyessä, ja jossa madaltuva käyttöjännite ennemminkin hankaloittaa kuin helpottaa suunnittelua. Siksi yhä suurempi osa signaalinkäsittelystä pyritään tekemään digitaalisesti. Digitaalisen signaalinkäsittelyn ongelmat puolestaan liittyvät algoritmien tehokkaaseen toteuttamiseen siten, että piirien pinta-ala ja tehonkulutus eivät kasva liian suuriksi. Tässä kirjassa on tutkittu digitaalisessa lähettimessä tarvittavien digitaalisten suodattimien, ylössekoitusalgoritmien ja digitaalisesta analogiseksi -muuntimien toteuttamiseen liittyviä ongelmia. Tutkimustuloksia on sovellettu kolmannen sukupolven WCDMA-tukiasemalähettimen toteutuksessa. Lisäksi on tutkittu digitaalisesta analogiseksi -muuntimien lineaarisuuteen ja suorituskykyyn vaikuttavien seikkojen teoriaa, ja esitetty digitaalinen kalibrointialgoritmi muuntimen staattisen suorituskyvyn parantamiseksi. Algoritmi on toteutettu 16-bittisen muuntimen yhteydessä ja se on osoitettu toimivaksi mittauksin.reviewe