Strategies for enhancing DC gain and settling performance of amplifiers

The operational amplifier (op amp) is one of the most widely used and important building blocks in analog circuit design. High gain and high speed are two important properties of op amps because they determine the settling behavior of the op amps. As supply voltages decrease, the realization of high gain amplifiers with large Gain-Bandwidth-Products (GBW) has become challenging. The major focus in this dissertation is on the negative output impedance gain enhancement technique. The negative impedance gain enhancement technique offers potential for achieving very high gain and energy-efficient fast settling and is low-voltage compatible. Misconceptions that have limited the practical adoption of this gain enhancement technique are discussed. A new negative conductance gain enhancement technique was proposed. The proposed circuit generates a negative conductance with matching requirements for achieving very high DC gain that are less stringent than those for existing -g m gain enhancement schemes. The proposed circuit has potential for precise digital control of a very large DC gain. A prototype fully differential CMOS operational amplifier was designed and fabricated based on the proposed gain enhancement technique. Experimental results which showed a DC gain of 85dB and an output swing of 876mVp-p validated the fundamental performance characteristics of this technique. In a separate section, a new amplifier architecture with bandpass feedforward compensation is presented. It is shown that a bandpass feedforward path can be used to substantially extend the unity-gain-frequency of an operational amplifier. Simulation results predict significant improvements in rise time and settling performance and show that the bandpass compensation scheme is reasonably robust. In the final section, a new technique for asynchronous data recovery based upon using a delay line in the incoming data path is introduced. The proposed data recovery system is well suited for tight tolerance channels and coding systems supporting standards that limit the maximum number of consecutive 0\u27s and 1\u27s in a data stream. This system does not require clock recovery, suffers no loss of data during acquisition, has a reduced sensitivity to jitter in the incoming data and does not exhibit jitter enhancement associated with VCO tracking in a PLL

Ultra-Low-Power Wake-up Clock Design for SoC Applications

This thesis studies how to design an ultra-low-power wake-up clock circuit for SoCapplications that essentially consists of a resistor based reference circuit, switched-capacitor branch, an ultra-low-power amplifier, a VCO and a non-overlapping clockphase generator circuit. The circuit is designed in 180-nm CMOS technology usingCAD software for circuit design, layout design, pre and post-layout simulations.At first, a brief study of different clock-generation circuit architectures is made,wherein their merits and de-merits are discussed. This is followed by a study ofan ultra-low-power amplifier, ring-oscillator-based VCO, non-overlapping clockcircuits, the bias generation circuit and the current reference circuit. Additionally,a reference current chopping technique that further improves temperature stabilityis also described. Later, the report discusses the design and simulations of theactual implementation. Analysis of the design with regards to power consumption,temperature stability and layout area are carried out. The circuit operates at8.254kHz consuming 70.4nW with a temperature stability of 7.35ppm/◦C in thetemperature range of -40◦C to 75◦C. The final layout takes an area of 0.153mm2.The final design is analysed for its functionality at various process, voltage andtemperature corners. Future improvements in the current design are also discussedat the end of this report

Design techniques for clocking high performance signaling systems

Scaling of CMOS technology has progressed relentlessly for the past several decades. In order for this unprecedented scaling to benefit the performance of large digital systems, the communication bandwidth between integrated circuits (ICs) must scale accordingly. However, interconnect technology does not scale as aggressively, making communication between chips the major bottleneck in overall system performance. In addition, supply voltage scaling, increasing device leakage, and increased noise make existing signaling circuits inefficient and difficult to scale. In this thesis, both analog and digital enhancement techniques to mitigate scaling related issues and improve the performance of building blocks used in high- speed signaling systems are discussed. A digital-to-phase converter (DPC) with a resolution better than 100 femto-second resolution, a hybrid analog/digital clock and data recovery (CDR) architecture that improves the tracking range of tra- ditional CDRs by an order of magnitude, and a digital CDR architecture that obviates the need for the charge pump and the large area occupying loop filter, while achieving error-free operation are presented. Measured results obtained from the prototype chips are presented to illustrate the proposed design techniques.Keywords: CDR, PL

A Sub-10ps Time-to-Digital Converter with 204ns Dynamic Range For Time-resolved Imaging and Ranging Applications

Time-resolved quantization has become inherent in systems that incorporate a Time-of-Flight (ToF) or Time-of-Arrival (ToA) measurement. Such systems have diverse applications ranging from direct time-of-flight measurements in 3D ranging systems such as Radar and Lidar systems to imaging systems using Time-Correlated Single Photon Counting (TCSPC) (in fields such as nuclear instrumentation, molecular biology, artificial vision in computer systems, etc.). Time resolution in the order of picoseconds, especially in imaging applications has become important due to the increasing demands on the functionality and accuracy of the DSP (digital signal processing) in such systems. The increasing density of integration in CMOS implementations of such imaging and ranging systems places large constrains on area and power consumption. Furthermore, the increased variability of the range of the measurement quantities introduces an undesirable trade-off between dynamic range and precision/resolution. Therefore there is a need for time-to-digital converters which achieve high precision, high resolution and large dynamic range, without excessive costs in area and power. In this thesis, a wide range, high resolution TDC is designed to offer a timing resolution of less than 10ps and a dynamic range of 204.8ns. This is achieved by using a digitally-intensive hierarchical approach, using two looped structures, which incorporates a novel control logic algorithm. This guarantees accurate operation of the loops, removing the possibility of MSB errors in the digital word. Firstly the measurement is subdivided into 2 different sections: a coarse quantization and a fine quantization. Both of the conversion steps involve the use of a looped delay–line structure utilizing only 4 elements per delay line. This together with the control logic, makes the design of a wide dynamic range TDC achievable without excessive area and power consumption. The design has been simulated, fabricated and tested in the IBM 0.18μm technology. The proposed design achieves a resolution of 8.125ps with an input dynamic range of 204.8ns, a maximum input occurrence rate of 100MHz and a minimum dead time of 7.5ns. The fabricated TDC has a power consumption of < 20mW (1.8V supply; FSR signal at 4MS/s) and < 35mW at the maximum output rate of 100MS/s

CMOS Signal Synthesizers for Emerging RF-to-Optical Applications

The need for clean and powerful signal generation is ubiquitous, with applications spanning the spectrum from RF to mm-Wave, to into and beyond the terahertz-gap. RF applications including mobile telephony and microprocessors have effectively harnessed mixed-signal integration in CMOS to realize robust on-chip signal sources calibrated against adverse ambient conditions. Combined with low cost and high yield, the CMOS component of hand-held devices costs a few cents per part per million parts. This low cost, and integrated digital processing, make CMOS an attractive option for applications like high-resolution imaging and ranging, and the emerging 5-G communication space. RADAR techniques when expanded to optical frequencies can enable micrometers of resolution for 3D imaging. These applications, however, impose upto 100x more exacting specifications on power and spectral purity at much higher frequencies than conventional RF synthesizers. This generation of applications will present unconventional challenges for transistor technologies - whether it is to squeeze performance in the conventionally used spectrum, already wrung dry, or signal generation and system design in the relatively emptier mm-Wave to sub-mmWave spectrum, much of the latter falling in the ``Terahertz Gap". Indeed, transistor scaling and innovative device physics leading to new transistor topologies have yielded higher cut-off frequencies in CMOS, though still lagging well behind SiGe and III-V semiconductors. To avoid multimodule solutions with functionality partitioned across different technologies, CMOS must be pushed out of its comfort zone, and technology scaling has to have accompanying breakthroughs in design approaches not only at the system but also at the block level. In this thesis, while not targeting a specific application, we seek to formulate the obstacles in synthesizing high frequency, high power and low noise signals in CMOS and construct a coherent design methodology to address them. Based on this, three novel prototypes to overcome the limiting factors in each case are presented. The first half of this thesis deals with high frequency signal synthesis and power generation in CMOS. Outside the range of frequencies where the transistor has gain, frequency generation necessitates harmonic extraction either as harmonic oscillators or as frequency multipliers. We augment the traditional maximum oscillation frequency metric (fmax), which only accounts for transistor losses, with passive component loss to derive an effective fmax metric. We then present a methodology for building oscillators at this fmax, the Maximum Gain Ring Oscillator. Next, we explore generating large signals beyond fmax through harmonic extraction in multipliers. Applying concepts of waveform shaping, we demonstrate a Power Mixer that engineers transistor nonlinearity by manipulating the amplitudes and relative phase shifts of different device nodes to maximize performance at a specific harmonic beyond device cut-off. The second half proposes a new architecture for an ultra-low noise phase-locked loop (PLL), the Reference-Sampling PLL. In conventional PLLs, a noisy buffer converts the slow, low-noise sine-wave reference signal to a jittery square-wave clock against which the phase of a noisy voltage-controlled oscillator (VCO) is corrected. We eliminate this reference buffer, and measure phase error by sampling the reference sine-wave with the 50x faster VCO waveform already available on chip, and selecting the relevant sample with voltage proportional to phase error. By avoiding the N-squared multiplication of the high-power reference buffer noise, and directly using voltage-mode phase error to control the VCO, we eliminate several noisy components in the controlling loop for ultra-low integrated jitter for a given power consumption. Further, isolation of the VCO tank from any varying load, unlike other contemporary divider-less PLL architectures, results in an architecture with record performance in the low-noise and low-spur space. We conclude with work that brings together concepts developed for clean, high-power signal generation towards a hybrid CMOS-Optical approach to Frequency-Modulated Continuous-Wave (FMCW) Light-Detection-And-Ranging (LIDAR). Cost-effective tunable lasers are temperature-sensitive and have nonlinear tuning profiles, rendering precise frequency modulations or 'chirps' untenable. Locking them to an electronic reference through an electro-optic PLL, and electronically calibrating the control signal for nonlinearity and ambient sensitivity, can make such chirps possible. Approaches that build on the body of advances in electrical PLLs to control the performance, and ease the specification on the design of optical systems are proposed. Eventually, we seek to leverage the twin advantages of silicon-intensive integration and low-cost high-yield towards developing a single-chip solution that uses on-chip signal processing and phased arrays to generate precise and robust chirps for an electronically-steerable fine LIDAR beam

Time-to-digital converters and histogram builders in SPAD arrays for pulsed-LiDAR

Light Detection and Ranging (LiDAR) is a 3D imaging technique widely used in many applications such as augmented reality, automotive, machine vision, spacecraft navigation and landing. Pulsed-LiDAR is one of the most diffused LiDAR techniques which relies on the measurement of the round-trip travel time of an optical pulse back-scattered from a distant target. Besides the light source and the detector, Time-to-Digital Converters (TDCs) are fundamental components in pulsed-LiDAR systems, since they allow to measure the back-scattered photon arrival times and their performance directly impact on LiDAR system requirements (i.e., range, precision, and measurements rate). In this work, we present a review of recent TDC architectures suitable to be integrated in SPAD-based CMOS arrays and a review of data processing solutions to derive the TOF information. Furthermore, main TDC parameters and processing techniques are described and analyzed considering pulsed-LiDAR requirements

ポータビリティを意識したCMOSミックスドシグナルVLSI回路設計手法に関する研究

本研究は、半導体上に集積されたアナログ・ディジタル・メモリ回路から構成されるミクストシグナルシステムを別の製造プロセスへ移行することをポーティングとして定義し、効率的なポーティングを行うための設計方式と自動回路合成アルゴリズムを提案し、いくつかの典型的な回路に対する設計事例を示し、提案手法の妥当性を立証している。北九州市立大

Low jitter phase-locked loop clock synthesis with wide locking range

The fast growing demand of wireless and high speed data communications has driven efforts to increase the levels of integration in many communications applications. Phase noise and timing jitter are important design considerations for these communications applications. The desire for highly complex levels of integration using low cost CMOS technologies works against the minimization of timing jitter and phase noise for communications systems which employ a phase-locked loop for frequency and clock synthesis with on-chip VCO. This dictates an integrated CMOS implementation of the VCO with very low phase noise performance. The ring oscillator VCOs based on differential delay cell chains have been used successfully in communications applications, but thermal noise induced phase noise have to be minimized in order not to limit their applicability to some applications which impose stringent timing jitter and phase noise requirements on the PLL clock synthesizer. Obtaining lower timing jitter and phase noise at the PLL output also requires the minimization of noise in critical circuit design blocks as well as the optimization of the loop bandwidth of the PLL. In this dissertation the fundamental performance limits of CMOS PLL clock synthesizers based on ring oscillator VCOs are investigated. The effect of flicker and thermal noise in MOS transistors on timing jitter and phase noise are explored, with particular emphasis on source coupled NMOS differential delay cells with symmetric load elements. Several new circuit architectures are employed for the charge pump circuit and phase-frequency detector (PFD) to minimize the timing jitter due to the finite dead zone in the PFD and the current mismatch in the charge pump circuit. The selection of the optimum PLL loop bandwidth is critical in determining the phase noise performance at the PLL output. The optimum loop bandwidth and the phase noise performance of the PLL is determined using behavioral simulations. These results are compared with transistor level simulated results and experimental results for the PLL clock synthesizer fabricated in a 0.35 µm CMOS technology with good agreement. To demonstrate the proposed concept, a fully integrated CMOS PLL clock synthesizer utilizing integer-N frequency multiplier technique to synthesize several clock signals in the range of 20-400 MHz with low phase noise was designed. Implemented in a standard 0.35-µm N-well CMOS process technology, the PLL achieves a period jitter of 6.5-ps (rms) and 38-ps (peak-to-peak) at 216 MHz with a phase noise of -120 dBc/Hz at frequency offsets above 10 KHz. The specific research contributions of this work include (1) proposing, designing, and implementing a new charge pump circuit architecture that matches current levels and therefore minimizes one source of phase noise due to fluctuations in the control voltage of the VCO, (2) an improved phase-frequency detector architecture which has improved characteristics in lock condition, (3) an improved ring oscillator VCO with excellent thermal noise induced phase noise characteristics, (4) the application of selfbiased techniques together with fixed bias to CMOS low phase noise PLL clock synthesizer for digital video communications ,and (5) an analytical model that describes the phase noise performance of the proposed VCO and PLL clock synthesizer

Techniques for high-performance digital frequency synthesis and phase control

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2008.Includes bibliographical references (p. 183-190).This thesis presents a 3.6-GHz, 500-kHz bandwidth digital [delta][sigma] frequency synthesizer architecture that leverages a recently invented noise-shaping time-to-digital converter (TDC) and an all-digital quantization noise cancellation technique to achieve excellent in-band and out-of-band phase noise, respectively. In addition, a passive digital-to-analog converter (DAC) structure is proposed as an efficient interface between the digital loop filter and a conventional hybrid voltage-controlled oscillator (VCO) to create a digitally-controlled oscillator (DCO). An asynchronous divider structure is presented which lowers the required TDC range and avoids the divide-value-dependent delay variation. The prototype is implemented in a 0.13-am CMOS process and its active area occupies 0.95 mm². Operating under 1.5 V, the core parts, excluding the VCO output buffer, dissipate 26 mA. Measured phase noise at 3.67 GHz achieves -108 dBc/Hz and -150 dBc/Hz at 400 kHz and 20 MHz, respectively. Integrated phase noise at this carrier frequency yields 204 fs of jitter (measured from 1 kHz to 40 MHz). In addition, a 3.2-Gb/s delay-locked loop (DLL) in a 0.18-[mu]m CMOS for chip-tochip communications is presented. By leveraging the fractional-N synthesizer technique, this architecture provides a digitally-controlled delay adjustment with a fine resolution and infinite range. The provided delay resolution is less sensitive to the process, voltage, and temperature variations than conventional techniques. A new [delta][sigma] modulator enables a compact and low-power implementation of this architecture. A simple bang-bang detector is used for phase detection. The prototype operates at a 1.8-V supply voltage with a current consumption of 55 mA. The phase resolution and differential rms clock jitter are 1.4 degrees and 3.6 ps, respectively.by Chun-Ming Hsu.Ph.D

High bandwidth interchip communication for regular networks dc by Rajeevan Amirtharajah.

Thesis (M. Eng.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 1994.Includes bibliographical references (leaves 48-49).M.Eng