Prediction of phase noise and spurs in a nonlinear fractional-N frequency synthesizer

Integer boundary spurs appear in the passband of the loop response of fractional-N phase lock loops and are, therefore, a potentially significant component of the phase noise. In spite of measures guaranteeing spur-free modulator outputs, the interaction of the modulation noise from a divider controller with inevitable loop nonlinearities produces such spurs. This paper presents analytical predictions of the locations and amplitudes of the spurs and accompanying noise floor levels produced by interaction between a divider controller output and a PLL loop with a static nonlinearity. A key finding is that the spur locations and amplitudes can be estimated by using only the knowledge of the structure and pdf of the accumulated modulator noise and the nonlinearity. These predictions also offer new insights into why the spurs appear

4.48-GHz fractional- N frequency synthesizer with spurious-tone suppression via probability mass redistribution

A 4.48-GHz type-II charge pump fractional-N PLL implemented in a 0.18-μm BiCMOS process is presented. The divider controller's output is processed using a novel block, the probability mass redistributor, which statistically reconfigures the modulation noise such that fractional spurs are minimized. Measurements demonstrate in-band fractional spurs of -80 dBc. The solution, which is a drop-in modification of a conventional MASH structure, incurs a modulator area increase of 22%, and can be used in conjunction with other linearization strategies

A Low Jitter Wideband Fractional-N Subsampling Phase Locked Loop (SSPLL)

Frequency synthesizers have become a crucial building block in the evolution of modern communication systems and consumer electronics. The spectral purity performance of frequency synthesizers limits the achievable data-rate and presents a noise-power tradeoff. For communication standards such as LTE where the channel spacing is a few kHz, the synthesizers must provide high frequencies with sufficiently wide frequency tuning range and fine frequency resolutions. Such stringent performance must be met with a limited power and small chip area. In this thesis a wideband fractional-N frequency synthesizer based on a subsampling phase locked loop (SSPLL) is presented. The proposed synthesizer which has a frequency resolution less than 100Hz employs a digital fractional controller (DFC) and a 10-bit digital-to-time converter (DTC) to delay the rising edges of the reference clock to achieve fractional phase lock. For fast convergence of the delay calibration, a novel two-step delay correlation loop (DCL) is employed. Furthermore, to provide optimum settling and jitter performance, the loop transfer characteristics during frequency acquisition and phase-lock are decoupled using a dual input loop filter (DILF). The fractional-N sub-sampling PLL (FNSSPLL) is implemented in a TSMC 40nm CMOS technology and occupies a total active area of 0.41mm^2. The PLL operates over frequency range of 2.8 GHz to 4.3 GHz (42% tuning range) while consuming 9.18mW from a 1.1V supply. The integrated jitter performance is better than 390 fs across all fractional frequency channel. The worst case fractional spur of -48.3 dBc occurs at a 650 kHz offset for a 3.75GHz fractional channel. The in-band phase noise measured at a 200 kHz offset is -112.5 dBc/Hz

The Telecommunications and Data Acquisition Report

This publication, one of a series formerly titled The Deep Space Network Progress Report, documents DSN progress in flight project support, tracking and data acquisition research and technology, network engineering, hardware and software implementation, and operations. In addition, developments in Earth-based radio technology as applied to geodynamics, astrophysics and the radio search for extraterrestrial intelligence are reported

Special Topics in Information Technology

This open access book presents thirteen outstanding doctoral dissertations in Information Technology from the Department of Electronics, Information and Bioengineering, Politecnico di Milano, Italy. Information Technology has always been highly interdisciplinary, as many aspects have to be considered in IT systems. The doctoral studies program in IT at Politecnico di Milano emphasizes this interdisciplinary nature, which is becoming more and more important in recent technological advances, in collaborative projects, and in the education of young researchers. Accordingly, the focus of advanced research is on pursuing a rigorous approach to specific research topics starting from a broad background in various areas of Information Technology, especially Computer Science and Engineering, Electronics, Systems and Control, and Telecommunications. Each year, more than 50 PhDs graduate from the program. This book gathers the outcomes of the thirteen best theses defended in 2019-20 and selected for the IT PhD Award. Each of the authors provides a chapter summarizing his/her findings, including an introduction, description of methods, main achievements and future work on the topic. Hence, the book provides a cutting-edge overview of the latest research trends in Information Technology at Politecnico di Milano, presented in an easy-to-read format that will also appeal to non-specialists

Performance enhancement techniques for low power digital phase locked loops

Desire for low-power, high performance computing has been at core of the symbiotic union between digital circuits and CMOS scaling. While digital circuit performance improves with device scaling, analog circuits have not gained these benefits. As a result, it has become necessary to leverage increased digital circuit performance to mitigate analog circuit deficiencies in nanometer scale CMOS in order to realize world class analog solutions. In this thesis, both circuit and system enhancement techniques to improve performance of clock generators are discussed. The following techniques were developed: (1) A digital PLL that employs an adaptive and highly efficient way to cancel the effect of supply noise, (2) a supply regulated DPLL that uses low power regulator and improves supply noise rejection, (3) a digital multiplying DLL that obviates the need for high-resolution TDC while achieving sub-picosecond jitter and excellent supply noise immunity, and (4) a high resolution TDC based on a switched ring oscillator, are presented. Measured results obtained from the prototype chips are presented to illustrate the proposed design techniques

Energy-efficient wireline transceivers

Power-efficient wireline transceivers are highly demanded by many applications in high performance computation and communication systems. Apart from transferring a wide range of data rates to satisfy the interconnect bandwidth requirement, the transceivers have very tight power budget and are expected to be fully integrated. This thesis explores enabling techniques to implement such transceivers in both circuit and system levels. Specifically, three prototypes will be presented: (1) a 5Gb/s reference-less clock and data recovery circuit (CDR) using phase-rotating phase-locked loop (PRPLL) to conduct phase control so as to break several fundamental trade-offs in conventional receivers; (2) a 4-10.5Gb/s continuous-rate CDR with novel frequency acquisition scheme based on bang-bang phase detector (BBPD) and a ring oscillator-based fractional-N PLL as the low noise wide range DCO in the CDR loop; (3) a source-synchronous energy-proportional link with dynamic voltage and frequency scaling (DVFS) and rapid on/off (ROO) techniques to cut the link power wastage at system level. The receiver/transceiver architectures are highly digital and address the requirements of new receiver architecture development, wide operating range, and low power/area consumption while being fully integrated. Experimental results obtained from the prototypes attest the effectiveness of the proposed techniques

FPGA Implementation of the Front-End of a DOCSIS 3.0 Receiver

The introduction of cable television (CATV) in the 1940s and 1950s has significantly influenced communications technology. Originally supplying only one-way television programming, the CATV industry recognized the potential of two-way communications. Starting with the introduction of pay-per view services in the 1980s, two-way communications over CATV networks eventually expanded into supplying internet access services. The increased demand for CATV services, and thus the increased demand for CATV equipment, has led the CATV industry to develop interoperability standards. The primary standard now used by the CATV industry is the Data Over Cable Service Specification (DOCSIS). DOCSIS defines both the upstream (data towards the CATV provider) and downstream (data towards the CATV customer) transmission channels. This includes specifications for the modulators and demodulators used in these channels. The number of manufacturers of CATV modulators and demodulators has greatly increased over the last twenty years and continues to do so. As the number of competitive CATV equipment suppliers increases, these manufacturers must look to ways to remain competitive by reducing time-to-market and costs associated with equipment design, as well as allowing their designs to be flexible so that they may adapt to the improvements in DOCSIS. In the past, manufacturers have primarily used Application Specific Integrated Circuits (ASICs) to implement digital hardware designs for CATV equipment. ASICs have a very high initial setup cost and do not allow for system modifications without a complete redesign. Recently, Field Programmable Gate Array (FPGA) technology has been introduced that allows manufacturers to both modify their designed digital hardware structures without a complete physical hardware redesign, as well as providing a reduced initial setup cost. Although in the long term, ASICs provide a cheaper alternative to FPGAs when produced in quantity, FPGAs provide quicker time-to-market in new product development and allow changes to made after initial release. This ability to change designs after release and the quicker time-to-market has led manufacturers to adopt FPGAs in new products. A critical component in the upstream channel of a DOCSIS compliant system is the Quadrature Amplitude Modulated (QAM) receiver. The data received at the QAM receiver have undergone several impairments including additive noise, timing offset, and frequency and phase mismatches between the transmitted modulated signal and the signal received at the demodulator. It is the function of the front-end of the receiver to correct for these impairments. This thesis presents methods for, and an example of, the design and implementation of a DOCSIS compliant QAM receiver front-end that corrects for timing, phase and frequency impairments experienced in the upstream communication channel when additive noise is present. The circuits presented are designed and implemented to reduce hardware costs when using FPGA technology. In addition, the circuits designed do not use proprietary logic, which gives designers more flexibility when implementing their own demodulator front-end circuitry. The FPGA implementation presented in this thesis achieves an average MER of 54.3 dB in a no-noise channel and close to 31 dB MER in a 25 dBc AWGN channel. The overall design uses 65 dedicated 18-bit by 18-bit multipliers and 2,970 bytes of RAM to implement the digital front-end of the receiver

INJECTION-LOCKING TECHNIQUES FOR MULTI-CHANNEL ENERGY EFFICIENT TRANSMITTER

Ph.DDOCTOR OF PHILOSOPH