RF CMOS quadrature voltage-controlled oscillator design using superharmonic coupling method.

Chung, Wai Fung.Thesis (M.Phil.)--Chinese University of Hong Kong, 2007.Includes bibliographical references (leaves 98-100).Abstracts in English and Chinese.摘要 --- p.IIIACKNOWLEDGEMENT --- p.IVCONTENTS --- p.VLIST OF FIGURES --- p.VIIILIST OF TABLES --- p.XLIST OF TABLES --- p.XChapter CHAPTER 1 --- INTRODUCTION --- p.1Chapter 1.1 --- Motivation --- p.1Chapter 1.2 --- Receiver Architecture --- p.3Chapter 1.2.1 --- Zero-IF Receivers --- p.4Chapter 1.2.2 --- Low-IF Receivers --- p.6Chapter 1.2.2.1 --- Hartley Architecture --- p.7Chapter 1.2.2.2 --- Weaver Architecture --- p.9Chapter 1.3 --- Image-rejection ratio --- p.10Chapter 1.4 --- Thesis Organization --- p.12Chapter CHAPTER 2 --- FUNDAMENTALS OF OSCILLATOR --- p.13Chapter 2.1 --- Basic Oscillator Theory --- p.13Chapter 2.2 --- Varactor --- p.15Chapter 2.3 --- Inductor --- p.17Chapter 2.4 --- Phase noise --- p.22Chapter 2.4.1 --- The Leeson ´ةs phase noise expression --- p.24Chapter 2.4.2 --- Linear model --- p.25Chapter 2.4.3 --- Linear Time-Variant phase noise model --- p.28Chapter CHAPTER 3 --- FULLY-INTEGRATED CMOS OSCILLATOR DESIGN --- p.31Chapter 3.1 --- Ring oscillator --- p.31Chapter 3.2 --- LC oscillator --- p.33Chapter 3.2.1 --- LC-tank resonator --- p.34Chapter 3.2.2 --- Negative transconductance --- p.36Chapter 3.3 --- Generation of quadrature phase signals --- p.39Chapter 3.4 --- Quadrature VCO topologies --- p.41Chapter 3.4.1 --- Parallel-coupled QVCO --- p.41Chapter 3.4.2 --- Series-coupled QVCO --- p.46Chapter 3.4.3 --- QVCO with Back-gate Coupling --- p.47Chapter 3.4.4 --- QVCO using superharmonic coupling --- p.49Chapter 3.5 --- Novel QVCO using back-gate superharmonic coupling --- p.52Chapter 3.5.1 --- Tuning range --- p.54Chapter 3.5.2 --- Negative gm --- p.55Chapter 3.5.3 --- Phase noise calculation --- p.56Chapter 3.5.4 --- Coupling coefficient --- p.57Chapter 3.5.5 --- Low-voltage and low-power design --- p.59Chapter 3.5.6 --- Layout Consideration --- p.61Chapter 3.5.6.1 --- Symmetrical Layout and parasitics --- p.61Chapter 3.5.6.2 --- Metal width and number of vias --- p.63Chapter 3.5.6.3 --- Substrate contact and guard ring --- p.63Chapter 3.5.7 --- Simulation Results --- p.65Chapter 3.5.7.1 --- Frequency and output power --- p.65Chapter 3.5.7.2 --- Quadrature signal generation --- p.67Chapter 3.5.7.3 --- Tuning range --- p.67Chapter 3.5.7.4 --- Power consumption --- p.68Chapter 3.5.7.5 --- Phase noise --- p.69Chapter 3.6 --- Polyphase filter and Single-sideband mixer design --- p.70Chapter 3.6.1 --- Polyphase filter --- p.72Chapter 3.6.2 --- Layout Consideration --- p.74Chapter 3.6.3 --- Simulation results --- p.76Chapter 3.7 --- Comparison with parallel-coupled QVCO --- p.78Chapter CHAPTER 4 --- EXPERIMENTAL RESULTS --- p.80Chapter 4.1 --- Test Fixture --- p.82Chapter 4.2 --- Measurement set-up --- p.84Chapter 4.3 --- Measurement results --- p.86Chapter 4.3.1 --- Proposed QVCO using back-gate superharmonic coupling --- p.86Chapter 4.3.1.1 --- Output Spectrum --- p.86Chapter 4.3.1.2 --- Tuning range --- p.87Chapter 4.3.1.3 --- Phase noise --- p.88Chapter 4.3.1.4 --- Power consumption --- p.88Chapter 4.3.1.5 --- Image-rejection ratio --- p.89Chapter 4.3.2 --- Parallel-coupled QVCO --- p.90Chapter 4.3.2.1 --- Output spectrum --- p.90Chapter 4.3.2.2 --- Power consumption --- p.90Chapter 4.3.2.3 --- Tuning range --- p.91Chapter 4.3.2.4 --- Phase noise --- p.92Chapter 4.3.3 --- Comparison between proposed and parallel-coupled QVCO --- p.93Chapter CHAPTER 5 --- CONCLUSIONS --- p.95Chapter 5.1 --- Conclusions --- p.95Chapter 5.2 --- Future work --- p.97REFERENCES --- p.9

Design of injection locked frequency divider in 65nm CMOS technology for mmW applications

In this paper, an Injection Locking Frequency Divider (ILFD) in 65 nm RF CMOS Technology for applications in millimeter-wave (mm-W) band is presented. The proposed circuit achieves 12.69% of locking range without any tuning mechanism and it can cover the entire mm-W band in presence of Process, Voltage and Temperature (PVT) variations by changing the Injection Locking Oscillator (ILO) voltage control. A design methodology flow is proposed for ILFD design and an overview regarding CMOS capabilities and opportunities for mm-W transceiver implementation is also exposed.Postprint (published version

System-on-Package Low-Power Telemetry and Signal Conditioning unit for Biomedical Applications

Recent advancements in healthcare monitoring equipments and wireless communication technologies have led to the integration of specialized medical technology with the pervasive wireless networks. Intensive research has been focused on the development of medical wireless networks (MWN) for telemedicine and smart home care services. Wireless technology also shows potential promises in surgical applications. Unlike conventional surgery, an expert surgeon can perform the surgery from a remote location using robot manipulators and monitor the status of the real surgery through wireless communication link. To provide this service each surgical tool must be facilitated with smart electronics to accrue data and transmit the data successfully to the monitoring unit through wireless network. To avoid unwieldy wires between the smart surgical tool and monitoring units and to reap the benefit of excellent features of wireless technology, each smart surgical tool must incorporate a low-power wireless transmitter. Low-power transmitter with high efficiency is essential for short range wireless communication. Unlike conventional transmitters used for cellular communication, injection-locked transmitter shows greater promises in short range wireless communication. The core block of an injection-locked transmitter is an injection-locked oscillator. Therefore, this research work is directed towards the development of a low-voltage low-power injection-locked oscillator which will facilitate the development of a low-power injection-locked transmitter for MWN applications. Structure of oscillator and types of injection are two crucial design criteria for low-power injection-locked oscillator design. Compared to other injection structures, body-level injection offers low-voltage and low-power operation. Again, conventional NMOS/PMOS-only cross-coupled LC oscillator can work with low supply voltage but the power consumption is relatively high. To overcome this problem, a self-cascode LC oscillator structure has been used which provides both low-voltage and low-power operation. Body terminal coupling is used with this structure to achieve injection-locking. Simulation results show that the self-cascode structure consumes much less power compared to that of the conventional structure for the same output swing while exhibiting better phase noise performance. Usage of PMOS devices and body bias control not only reduces the flicker noise and power consumption but also eliminates the requirements of expensive fabrication process for body terminal access

A Q-band Direct Divide-by-4 Injection-Locked Frequency Divider with Quadrature Outputs

[[abstract]]A divide-by-4 injection-locked frequency divider is designed for applications in the millimeter-wave frequency range. The proposed circuit also features in quadrature phase outputs by using a quadrature voltage-controlled oscillator. The input signal is injected into the common-mode node at the tail current source directly. Implemented in a 0.13 μm CMOS technology, the core circuit consumes dc power of 3.66mW with 1.2 V supply voltage. The operation range achieves 1.95 GHz. The entire die occupies an area of 974Ã726 um 2 .[[conferencetype]]國際[[conferencedate]]20100928~2010093

Low-power transceiver design for mobile wireless chemical biological sensors

The design of a smart integrated chemical sensor system that will enhance sensor performance and compatibility to Ad hoc network architecture remains a challenge. This work involves the design of a Transceiver for a mobile chemical sensor. The transceiver design integrates all building blocks on-chip, including a low-noise amplifier with an input-matching network, a Voltage Controlled Oscillator with injection locking, Gilbert cell mixers, and a Class E Power amplifier making it as a single-chip transceiver. This proposed low power 2GHz transceiver has been designed in TSMC 0.35~lm CMOS process using Cadence electronic design automation tools. Post layout HSPICE simulation indicates that Design meets the separation of noise levels by 52dB and 42dB in transmitter and receiver respectively with power consumption of 56 mW and 38 mW in transmit and receive mode

Stochastic analysis of cycle slips in injection-locked oscillators and analog frequency dividers

A detailed investigation of cycle slips in injection-locked oscillators (ILOs) and analog frequency dividers is presented. This nonlinear phenomenon gives rise to a temporal desynchronization between the injected oscillator and the input source due to noise perturbations. It involves very different time scales so even envelope-transient-based Monte Carlo analyses may suffer from high computational cost. The analysis method is based on an initial extraction of a reduced-order nonlinear model of the injected oscillator based on harmonic-balance simulations. This model has been improved with a more accurate description of oscillation dependence on the input source either at the fundamental frequency or, in the case of a frequency divider, at a given harmonic frequency. The reduced-order model enables an efficient stochastic analysis of the system based on the use of the associated Fokker-Planck equation in the phase probability density function. Several methods for the solution of the associated Fokker-Planck equation are compared with one of them being applicable under a wider range of system specifications. The analysis enables the prediction of the parameter-space regions that are best protected against cycle slips. The technique has been applied to two microwave ILOs and has been validated through commercial software envelope simulations in situations where the computational cost of the envelope simulations was acceptable, and through measurements. The measurement procedure of the cycle slipping phenomenon has been significantly improved with respect to previous work.This work was supported by the Spanish Ministry of Economy and Competitiveness under Contract TEC2011-29264-C03-01

Clock Generation Design for Continuous-Time Sigma-Delta Analog-To-Digital Converter in Communication Systems

Software defined radio, a highly digitized wireless receiver, has drawn huge attention in modern communication system because it can not only benefit from the advanced technologies but also exploit large digital calibration of digital signal processing (DSP) to optimize the performance of receivers. Continuous-time (CT) bandpass sigma-delta (ΣΔ) modulator, used as an RF-to-digital converter, has been regarded as a potential solution for software defined ratio. The demand to support multiple standards motivates the development of a broadband CT bandpass ΣΔ which can cover the most commercial spectrum of 1GHz to 4GHz in a modern communication system. Clock generation, a major building block in radio frequency (RF) integrated circuits (ICs), usually uses a phase-locked loop (PLL) to provide the required clock frequency to modulate/demodulate the informative signals. This work explores the design of clock generation in RF ICs. First, a 2-16 GHz frequency synthesizer is proposed to provide the sampling clocks for a programmable continuous-time bandpass sigma-delta (ΣΔ) modulator in a software radio receiver system. In the frequency synthesizer, a single-sideband mixer combines feed-forward and regenerative mixing techniques to achieve the wide frequency range. Furthermore, to optimize the excess loop delay in the wideband system, a phase-tunable clock distribution network and a clock-controlled quantizer are proposed. Also, the false locking of regenerative mixing is solved by controlling the self-oscillation frequency of the CML divider. The proposed frequency synthesizer performs excellent jitter performance and efficient power consumption. Phase noise and quadrature phase accuracy are the common tradeoff in a quadrature voltage-controlled oscillator. A larger coupling ratio is preferred to obtain good phase accuracy but suffer phase noise performance. To address these fundamental trade-offs, a phasor-based analysis is used to explain bi-modal oscillation and compute the quadrature phase errors given by inevitable mismatches of components. Also, the ISF is used to estimate the noise contribution of each major noise source. A CSD QVCO is first proposed to eliminate the undesired bi-modal oscillation and enhance the quadrature phase accuracy. The second work presents a DCC QVCO. The sophisticated dynamic current-clipping coupling network reduces injecting noise into LC tank at most vulnerable timings (zero crossing points). Hence, it allows the use of strong coupling ratio to minimize the quadrature phase sensitivity to mismatches without degrading the phase noise performance. The proposed DCC QVCO is implemented in a 130-nm CMOS technology. The measured phase noise is -121 dBc/Hz at 1MHz offset from a 5GHz carrier. The QVCO consumes 4.2mW with a 1-V power supply, resulting in an outstanding Figure of Merit (FoM) of 189 dBc/Hz. Frequency divider is one of the most power hungry building blocks in a PLL-based frequency synthesizer. The complementary injection-locked frequency divider is proposed to be a low-power solution. With the complimentary injection schemes, the dividers can realize both even and odd division modulus, performing a more than 100% locking range to overcome the PVT variation. The proposed dividers feature excellent phase noise. They can be used for multiple-phase generation, programmable phase-switching frequency dividers, and phase-skewing circuits

Optimized design of frequency dividers based on varactor-inductor cells

This paper presents an in-depth analysis of a recently proposed frequency divider by two, which is based on a parallel connection of varactor-inductor cells, in a differential operation at the subharmonic frequency. The analytical study of a single-cell divider enables the derivation of a real equation governing the circuit at the frequency-division threshold. This equation is used for a detailed investigation of the impact of the circuit elements on the input-amplitude threshold and the frequency bandwidth. Insight provided by the analytical formulation enables the derivation of a thorough synthesis methodology for multiple-cell dividers, usable in harmonic balance with an auxiliary generator at the divided frequency. Two different applications of this topology are demonstrated: a dual-phase divider and a dual-band frequency divider. The former is obtained by using Marchand balun to deliver 180 ° phase-shifted signals to the two dividers. On the other hand, the dual-band divider is based on a novel configuration which combines cells with parallel varactors and cells with series varactors. Departing from the optimization procedure of the single-band divider, a simple synthesis method is presented to center the two division bands at the desired values. The techniques have been applied to three prototypes at 2.15 GHz, 1.85 GHz, and 1.75 GHz/3.95 GHz, respectively.This work was supported by the Spanish Ministry of Science and Innovation under project TEC2014-60283-C3-1-R and by the Parliament and University of Cantabria under the project Cantabria Explora 12-JP02-640.6

Design of Frequency divider with voltage vontrolled oscillator for 60 GHz low power phase-locked loops in 65 nm RF CMOS

Increasing memory capacity in mobile devices, is driving the need of high-data rates equipment. The 7 GHz band around 60 GHz provides the opportunity for multi-gigabit/sec wireless communication. It is a real opportunity for developing next generation of High-Definition (HD) devices. In the last two decades there was a great proliferation of Voltage Controlled Oscillator (VCO) and Frequency Divider (FD) topologies in RF ICs on silicon, but reaching high performance VCOs and FDs operating at 60 GHz is in today's technology a great challenge. A key reason is the inaccuracy of CMOS active and passive device models at mm-W. Three critical issues still constitute research objectives at 60 GHz in CMOS: generation of the Local Oscillator (LO) signal (1), division of the LO signal for the Phase-Locked Loop (PLL) closed loop (2) and distribution of the LO signal (3). In this Thesis, all those three critical issues are addressed and experimentally faced-up: a divide-by-2 FD for a PLL of a direct-conversion transceiver operating at mm-W frequencies in 65 nm RF CMOS technology has been designed. Critical issues such as Process, Voltage and Temperature (PVT) variations, Electromagnetic (EM) simulations and power consumption are addressed to select and design a FD with high frequency dividing range. A 60 GHz VCO is co-designed and integrated in the same die, in order to provide the FD with mm-W input signal. VCOs and FDs play critical roles in the PLL. Both of them constitute the PLL core components and they would need co-design, having a big impact in the overall performance especially because they work at the highest frequency in the PLL. Injection Locking FD (ILFD) has been chosen as the optimum FD topology to be inserted in the control loop of mm-W PLL for direct-conversion transceiver, due to the high speed requirements and the power consumption constraint. The drawback of such topology is the limited bandwidth, resulting in narrow Locking Range (LR) for WirelessHDTM applications considering the impact of PVT variations. A simulation methodology is presented in order to analyze the ILFD locking state, proposing a first divide-by-2 ILFD design with continuous tuning. In order to design a wide LR, low power consumption ILFD, the impacts of various alternatives of low/high Q tank and injection scheme are deeply analysed, since the ILFD locking range depends on the Q of the tank and injection efficiency. The proposed 3-bit dual-mixing 60 GHz divide-by-2 LC-ILFD is designed with an accumulation of switching varactors binary scaled to compensate PVT variations. It is integrated in the same die with a 4-bit 60 GHz LC-VCO. The overall circuit is designed to allow measurements of the singles blocks stand-alone and working together. The co-layout is carried on with the EM modelling process of passives devices, parasitics and transmission lines extracted from the layout. The inductors models provided by the foundry are qualified up to 40 GHz, therefore the EM analysis is a must for post-layout simulation. The PVT variations have been simulated before manufacturing and, based on the results achieved, a PLL scheme PVT robust, considering frequency calibration, has been patented. The test chip has been measured in the CEA-Leti (Grenoble) during a stay of one week. The operation principle and the optimization trade-offs among power consumption, and locking ranges of the final selected ILFD topology have been demonstrated. Even if the experimental results are not completely in agreement with the simulations, due to modelling error and inaccuracy, the proposed technique has been validated with post-measurement simulations. As demonstrated, the locking range of a low-power, discrete tuned divide-by-2 ILFD can be enhanced by increasing the injection efficiency, without the drawbacks of higher power consumption and chip area. A 4-bits wide tuning range LC-VCO for mm-W applications has been co-designed using the selected 65 nm CMOS process.Postprint (published version

Millimetre-wave optically injection-locked oscillators for radio-over-fibre systems

Theoretical analysis and experimental results for millimetre-wave optically injection-locked oscillators are presented in this thesis. Such oscillators can be employed to replace conventional photodiode plus amplifier receivers for local oscillator signal reception in millimetre-wave radio-over-fibre systems. The theories for electrical injection-locked oscillators are reviewed in detail. Three differences between Adler’s and Kurokawa’s equations for locking bandwidth are highlighted for the first time. These differences are the absence of l/cos# factor in Adler’s equation, larger bandwidth predicted by Kurokawa’s equation, and a difference in definition of Q factors. Locking bandwidth equations for optically injection-locked oscillators are developed based on the theories of electrical injection-locked oscillators and are then used to design optically injection-locked oscillators. A novel millimetre-wave indirect optically injection-locked oscillator is presented. An edge-coupled photodiode is used to detect the optical signal. Negative resistance and computer simulation techniques were used for predicting the free running oscillation frequency. The maximum output power of the oscillator is 5.3 dBm, and the maximum locking bandwidth is measured to be 2.6 MHz with an output power o f-12 dBm. Results from a comparison with conventional optical receivers show that the gain of the optically injection-locked oscillator is more than 10 dB higher than that of a photodiode plus amplifier receiver, that the oscillator output power remains constant with input signal power variations whereas the output power of the photodiode plus amplifier receiver changes (linearly) with the input signal power, and that, at high-offset frequencies, the phase noise of the optically injection-locked oscillator is much lower than that of the photodiode plus amplifier receiver. These advantages make the optically injection-locked oscillator an ideal replacement for the photodiode plus amplifier receiver in radio-over-fibre systems. An improved wide-band design for millimetre-wave optically injection-locked oscillators is presented for future work