33,237 research outputs found

    Analysis of Clock Buffer Phase Noise

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    This paper presents a phase noise model for clock buffers. The model can be used to predict the phase noise introduced by clock buffers and to gain insight into phase noise transfer mechanisms in clock buffers. Based on the models, techniques for low phase noise clock buffer design are derived. The analytical results presented here have good agreement with simulation and measurement results

    차량용 CIS Interface 를 위한 All-Digital Phase-Locked Loop 의 설계 및 분석

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    학위논문 (석사) -- 서울대학교 대학원 : 공과대학 전기·정보공학부, 2021. 2. 정덕균.This thesis presents design techniques for All-Digital Phase-Locked Loop (ADPLL) assisting the automotive CMOS image sensor (CIS) interface. To target Gear 3 of the automotive physical system, the proposed AD-PLL has a wide operation range, low RMS jitter, and high PVT tolerance characteristics. Detailed analysis of the loop dynamics and the noise analysis of AD-PLL are done by using Matlab and Verilog behavioral modeling simulation before an actual design. Based on that analysis, the optimal DLF gain configurations are yielded, and also, accurate output responses and performance are predictable. The design techniques to reduce the output RMS jitter are discussed thoroughly and utilized for actual implementation. The proposed AD-PLL is fabricated in the 40 nm CMOS process and occupies an effective area of 0.026 mm2. The PLL output clock pulses exhibit an RMS jitter of 827 fs at 2 GHz. The power dissipation is 5.8 mW at 2 GHz, where the overall supply voltage domain is 0.9 V excluding the buffer which is 1.1 V domain.본 논문에서는 자동차 CMOS 이미지 센서 (CIS) 인터페이스를 지원하 는 AD-PLL 을 제안한다. Automotive Physical 시스템의 Gear 3 를 지원하기 위해 제안된 AD-PLL 은 1.5 GHz 에서 3 GHz 의 동작 주파수를 가지며, 낮 은 RMS Jitter 및 PVT 변화에 대한 높은 둔감성을 갖는다. 설계에 앞서서 Matlab 및 Verilog Behavioral Simulation 을 통해 Loop system 의 역학에 대한 자세한 분석 및 AD-PLL 의 Noise 분석을 수행하였고, 이 분석을 기반으로 최적의 DLF gain 과 정확한 출력 응답 및 성능을 예측 할 수 있었다. 또한, 출력의 Phase Noise 와 RMS Jitter 를 줄이기 위한 설계 기법을 자세히 다루고 있으며 이를 실제 구현에 활용했다. 제안된 회로는 40 nm CMOS 공정으로 제작되었으며 Decoupling Cap 을 제외하고 0.026 mm2 의 유효 면적을 차지한다. 측정된 출력 Clock 신호의 RMS Jitter 값은 2 GHz 에서 827 fs 이며, 총 5.8 mW의 Power 를 소비한다. 이 때, 전체적인 공급 전압은 0.9 V 이며, Buffer 의 Power 만이 1.1 V 를 사용하 였다.ABSTRACT I CONTENTS II LIST OF FIGURES IV LIST OF TABLES VII CHAPTER 1 INTRODUCTION 1 1.1 MOTIVATION 1 1.2 THESIS ORGANIZATION 3 CHAPTER 2 BACKGROUND ON ALL-DIGITAL PLL 4 2.1 OVERVIEW 4 2.2 BUILDING BLOCKS OF AD-PLL 7 2.2.1 TIME-TO-DIGITAL CONVERTER 7 2.2.2 DIGITALLY-CONTROLLED OSCILLATOR 10 2.2.3 DIGITAL LOOP FILTER 13 2.2.4 DELTA-SIGMA MODULATOR 16 2.3 PHASE NOISE ANALYSIS OF AD-PLL 20 2.3.1 BASIC ASSUMPTION OF LINEAR ANALYSIS 20 2.3.2 NOISE SOURCES OF AD-PLL 21 2.3.3 EFFECTS OF LOOP DELAY ON AD-PLL 24 2.3.4 PHASE NOISE ANALYSIS OF PROPOSED AD-PLL 26 CHAPTER 3 DESIGN OF ALL-DIGITAL PLL 28 3.1 DESIGN CONSIDERATION 28 3.2 OVERALL ARCHITECTURE 30 3.3 CIRCUIT IMPLEMENTATION 32 3.3.1 PFD-TDC 32 3.3.2 DCO 37 3.3.3 DIGITAL BLOCK 43 3.3.4 LEVEL SHIFTING BUFFER AND DIVIDER 45 CHAPTER 4 MEASUREMENT AND SIMULATION RESULTS 52 4.1 DIE PHOTOMICROGRAPH 52 4.2 MEASUREMENT SETUP 54 4.3 TRANSIENT ANALYSIS 57 4.4 PHASE NOISE AND SPUR PERFORMANCE 59 4.4.1 FREE-RUNNING DCO 59 4.4.2 PLL PERFORMANCE 61 4.5 PERFORMANCE SUMMARY 65 CHAPTER 5 CONCLUSION 67 BIBLIOGRAPHY 68 초 록 72Maste

    A Low Noise Sub-Sampling PLL in Which Divider Noise Is Eliminated and PD-CP Noise Is not multiplied by N^2

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    This paper presents a 2.2-GHz low jitter sub-sampling based PLL. It uses a phase-detector/charge-pump (PD/CP)that sub-samples the VCO output with the reference clock. In contrast to what happens in a classical PLL, the PD/CP noise is not multiplied by N2 in this sub-sampling PLL, resulting in a low noise contribution from the PD/CP. Moreover, no frequency divider is needed in the locked state and hence divider noise and power can be eliminated. An added frequency locked loop guarantees correct frequency locking without degenerating jitter performance when in lock. The PLL is implemented in a standard 0.18- m CMOS process. It consumes 4.2 mA from a 1.8 V supply and occupies an active area of 0.4 X 0.45 m

    Analysis and equalization of data-dependent jitter

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    Data-dependent jitter limits the bit-error rate (BER) performance of broadband communication systems and aggravates synchronization in phase- and delay-locked loops used for data recovery. A method for calculating the data-dependent jitter in broadband systems from the pulse response is discussed. The impact of jitter on conventional clock and data recovery circuits is studied in the time and frequency domain. The deterministic nature of data-dependent jitter suggests equalization techniques suitable for high-speed circuits. Two equalizer circuit implementations are presented. The first is a SiGe clock and data recovery circuit modified to incorporate a deterministic jitter equalizer. This circuit demonstrates the reduction of jitter in the recovered clock. The second circuit is a MOS implementation of a jitter equalizer with independent control of the rising and falling edge timing. This equalizer demonstrates improvement of the timing margins that achieve 10/sup -12/ BER from 30 to 52 ps at 10 Gb/s

    Metrological characterization of the pulsed Rb clock with optical detection

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    We report on the implementation and the metrological characterization of a vapor-cell Rb frequency standard working in pulsed regime. The three main parts that compose the clock, physics package, optics and electronics, are described in detail in the paper. The prototype is designed and optimized to detect the clock transition in the optical domain. Specifically, the reference atomic transition, excited with a Ramsey scheme, is detected by observing the interference pattern on a laser absorption signal. \ The metrological analysis includes the observation and characterization of the clock signal and the measurement of frequency stability and drift. In terms of Allan deviation, the measured frequency stability results as low as 1.7×1013 τ1/21.7\times 10^{-13} \ \tau^{-1/2}, τ\tau being the averaging time, and reaches the value of few units of 101510^{-15} for τ=104\tau=10^{4} s, an unprecedent achievement for a vapor cell clock. We discuss in the paper the physical effects leading to this result with particular care to laser and microwave noises transferred to the clock signal. The frequency drift, probably related to the temperature, stays below 101410^{-14} per day, and no evidence of flicker floor is observed. \ We also mention some possible improvements that in principle would lead to a clock stability below the 101310^{-13} level at 1 s and to a drift of few units of 101510^{-15} per day

    A 90 nm CMOS 16 Gb/s Transceiver for Optical Interconnects

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    Interconnect architectures which leverage high-bandwidth optical channels offer a promising solution to address the increasing chip-to-chip I/O bandwidth demands. This paper describes a dense, high-speed, and low-power CMOS optical interconnect transceiver architecture. Vertical-cavity surface-emitting laser (VCSEL) data rate is extended for a given average current and corresponding reliability level with a four-tap current summing FIR transmitter. A low-voltage integrating and double-sampling optical receiver front-end provides adequate sensitivity in a power efficient manner by avoiding linear high-gain elements common in conventional transimpedance-amplifier (TIA) receivers. Clock recovery is performed with a dual-loop architecture which employs baud-rate phase detection and feedback interpolation to achieve reduced power consumption, while high-precision phase spacing is ensured at both the transmitter and receiver through adjustable delay clock buffers. A prototype chip fabricated in 1 V 90 nm CMOS achieves 16 Gb/s operation while consuming 129 mW and occupying 0.105 mm^2

    A Robust 43-GHz VCO in CMOS for OC-768 SONET Applications

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    In this paper, we present a 43-GHz LC-VCO in 0.13-/spl mu/m CMOS for use in SONET OC-768 optical networks. A tuned output buffer is used to provide 1.3 V/sub p-p/ (single-ended) into a 90-fF capacitive load as is required when the VCO is used in typical clock and data recovery (CDR) circuits. Phase noise is -90 dBc/Hz at a 1-MHz offset from the carrier; this meets SONET jitter specifications. The design has a tune range of 4.2%. The VCO, including output buffers, consumes 14 mA from a 1-V supply and occupies 0.06 mm/sup 2/ of die area. Modern CMOS process characteristics and the high center frequency of this design mean that the tank loss is not dominated by the integrated inductor, but rather by the tank capacitance. An area-efficient inductor design that does not require any optimization is used

    Coherent Population Trapping Resonances in Buffer Gas-filled Cs Vapor Cells with Push-Pull Optical Pumping

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    We report on a theoretical study and experimental characterization of coherent population trapping (CPT) resonances in buffer gas-filled vapor cells with push-pull optical pumping (PPOP) on Cs D1 line. We point out that the push-pull interaction scheme is identical to the so-called lin per lin polarization scheme. Expressions of the relevant dark states, as well as of absorption, are reported. The experimental setup is based on the combination of a distributed feedback (DFB) diode laser, a pigtailed intensity Mach-Zehnder electro-optic modulator (MZ EOM) for optical sidebands generation and a Michelson-like interferometer. A microwave technique to stabilize the transfer function operating point of the MZ EOM is implemented for proper operation. A CPT resonance contrast as high as 78% is reported in a cm-scale cell for the magnetic-field insensitive clock transition. The impact of the laser intensity on the CPT clock signal key parameters (linewidth - contrast - linewidth/contrast ratio) is reported for three different cells with various dimensions and buffer gas contents. The potential of the PPOP technique for the development of high-performance atomic vapor cell clocks is discussed.Comment: 28 pages, 12 figure

    A Differential 4-Path Highly Linear Widely Tunable On-Chip Band-Pass Filter

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    A passive switched capacitor RF band-pass filter with clock controlled center frequency is realized in 65nm CMOS. An off-chip transformer which acts as a balun, improves filter-Q and realizes impedance matching. The differential architecture reduces clock-leakage and suppresses selectivity around even harmonics of the clock. The filter has a constant -3dB bandwidth of 35MHz and can be tuned from 100MHz up to 1GHz. IIP3 is better than 19dBm, P1dB=2dBm and NF<;5.5dB at Pdiss=2mW to 16mW.\u

    Discrete-Time Mixing Receiver Architecture for RF-Sampling Software-Defined Radio

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    A discrete-time (DT) mixing architecture for RF-sampling receivers is presented. This architecture makes RF sampling more suitable for software-defined radio (SDR) as it achieves wideband quadrature demodulation and wideband harmonic rejection. The paper consists of two parts. In the first part, different downconversion techniques are classified and compared, leading to the definition of a DT mixing concept. The suitability of CT-mixing and RF-sampling receivers to SDR is also discussed. In the second part, we elaborate the DT-mixing architecture, which can be realized by de-multiplexing. Simulation shows a wideband 90° phase shift between I and Q outputs without systematic channel bandwidth limitation. Oversampling and harmonic rejection relaxes RF pre-filtering and reduces noise and interference folding. A proof-of-concept DT-mixing downconverter has been built in 65 nm CMOS, for 0.2 to 0.9 GHz RF band employing 8-times oversampling. It can reject 2nd to 6th harmonics by 40 dB typically and without systematic channel bandwidth limitation. Without an LNA, it achieves a gain of -0.5 to 2.5 dB, a DSB noise figure of 18 to 20 dB, an IIP3 = +10 dBm, and an IIP2 = +53 dBm, while consuming less than 19 mW including multiphase clock generation
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