Switched Capacitor Loop Filter 와 Source Switched Charge Pump 를 이용한 Phase-Locked Loop 의 설계

학위논문(석사) -- 서울대학교대학원 : 공과대학 전기·정보공학부, 2022.2. 정덕균.This thesis proposes a low integrated RMS jitter and low reference spur phase locked loop (PLL) using a switched capacitor loop filter and source switched charge pump. The PLL employs a single tunable charge pump which reduces current mis match across wide control voltage range and charge sharing effect to get high perfor mance of reference spur level. The switched capacitor loop filter is adopted to achieve insensitivity to temperature, supply voltage, and process variation of a resistor. The proposed PLL covers a wide frequency range and has a low integrated RMS jitter and low reference spur level to target various interface standards. The mechanism of switched capacitor loop filter and source switched charge pump is analyzed. Fabricated in 40 nm CMOS technology, the proposed analog PLL provides four phase for a quarter-rate transmitter, consumes 6.35 mW at 12 GHz using 750 MHz reference clock, and occupies an 0.008 mm2 with an integrated RMS jitter (10 kHz to 100 MHz) of 244.8 fs. As a result, the PLL achieves a figure of merit (FoM) of -244.2 dB with high power efficiency of 0.53 mW/GHz, and reference spur level is -60.3 dBc.본 논문에서는 낮은 RMS jitter 와 낮은 레퍼런스 스퍼를 가지며 스위치축전기 루프 필터와 소스 스위치 전하 펌프를 이용한 PLL 을 제안한다. 제안된 PLL 은 레퍼런스 스퍼의 성능을 위해 넓은 컨트롤 전압의 범위 동안 전류의 오차를 줄여주고 전하 공유 효과를 줄여주는 하나의 조절 가능한 전하 펌프를 사용하였다. 저항의 온도, 공급 전압, 공정 변화에 따른 민감도를 낮추기 위해 스위치 축전기 루프 필터가 사용되었다. 다양한 인터페이스 표준을 지원하기 위해 제안하는 PLL 은 넓은 주파수 범위를 지원하고 낮은 RMS jitter 와 낮은 레퍼런스 스퍼를 갖는다. 스위치 축전기 루프 필터와 소스 스위치 전하 펌프의 동작 원리에 대해 분석하였다. 40 nm CMOS 공정으로 제작되었으며, 제안된 회로는 quarter-rate 송신기를 위해 4 개의 phase 를 만들어내며 750 MHz 의 레퍼런스 클락을 이용하여 12 GHz 에서 6.35 mW 의 power 를 소모하고 0.008mm2 의 유효 면적을 차지하고 10 kHz 부터 100 MHz 까지 적분했을 때의 RMS jitter 값은 244.8fs 이다. 제안하는 PLL 은 -244.2 dB 의 FoM, 0.53 mW/GHz 의 power 효율을 달성했으며 레퍼런스 스퍼는 -60.3 dBc 이다CHAPTER 1 INTRODUCTION 1 1.1 MOTIVATION 1 1.2 THESIS ORGANIZATION 3 CHAPTER 2 BACKGROUNDS 4 2.1 CLOCK GENERATION IN SERIAL LINK 4 2.2 PLL BUILDING BLOCKS 6 2.2.1 OVERVIEW 6 2.2.2 PHASE FREQUENCY DETECTOR 7 2.2.3 CHARGE PUMP AND LOOP FILTER 9 2.2.4 VOLTAGE CONTROLLED OSCILLATOR 10 2.2.5 FREQUENCY DIVIDER 13 2.3 PLL LOOP ANALYSIS 15 CHAPTER 3 PLL WITH SWITCHED CAPACITOR LOOP FILTER AND SOURCE SWITCHED CHARGE PUMP 19 3.1 DESIGN CONSIDERATION 19 3.2 PROPOSED ARCHITECTURE 21 3.3 CIRCUIT IMPLEMENTATION 23 3.3.1 PHASE FREQUENCY DETECTOR 23 3.3.2 SOURCE SWITCHED CHARGE PUMP 26 3.3.3 SWITCHED CAPACITOR LOOP FILTER 30 3.3.4 VOLTAGE CONTROLLED OSCILLATOR 35 3.3.5 POST VCO AMPLIFIER 39 3.3.6 FREQUENCY DIVIDER 40 CHAPTER 4 MEASUREMENT RESULTS 43 4.1 CHIP PHOTOMICROGRAPH 43 4.2 MEASUREMENT SETUP 45 4.3 MEASURED PHASE NOISE AND REFERENCE SPUR 47 4.4 PERFORMANCE SUMMARY 50 CHAPTER 5 CONCLUSION 52 BIBLIOGRAPHY 53 초 록 58석

LOW-JITTER AND LOW-SPUR RING-OSCILLATOR-BASED PHASE-LOCKED LOOPS

Department of Electrical EngineeringIn recent years, ring-oscillator based clock generators have drawn a lot of attention due to the merits of high area efficiency, potentially wide tuning range, and multi-phase generation. However, the key challenge is how to suppress the poor jitter of ring oscillators. There have been many efforts to develop a ring-oscillator-based clock generator targeting very low-jitter performance. However, it remains difficult for conventional architectures to achieve both low RMS jitter and low levels of reference spurs concurrently while having a high multiplication factor. In this dissertation, a time-domain analysis is presented that provides an intuitive understanding of RMS jitter calculation of the clock generators from their phase-error correction mechanisms. Based on this analysis, we propose new designs of a ring-oscillator-based PLL that addresses the challenges of prior-art ring-based architectures. This dissertation introduces a ring-oscillator-based PLL with the proposed fast phase-error correction (FPEC) technique, which emulates the phase-realignment mechanism of an injection-locked clock multiplier (ILCM). With the FPEC technique, the phase error of the voltage-controlled oscillator (VCO) is quickly removed, achieving ultra-low jitter. In addition, in the transfer function of the proposed architecture, an intrinsic integrator is involved since it is naturally based on a PLL topology. The proposed PLL can thus have low levels of reference spurs while maintaining high stability even for a large multiplication factor. Furthermore, it presents another design of a digital PLL embodying the FPEC technique (or FPEC DPLL). To overcome the problem of a conventional TDC, a low-power optimally-spaced (OS) TDC capable of effectively minimizing the quantization error is presented. In the proposed FPEC DPLL, background digital controllers continuously calibrate the decision thresholds and the gain of the error correction by the loop to be optimal, thus dramatically reducing the quantization error. Since the proposed architecture is implemented in a digital fashion, the variables defining the characteristics of the loop can be easily estimated and calibrated by digital calibrators. As a result, the performances of an ultra-low jitter and the figure-of-merit can be achieved.clos