펄스 기반 피드 포워드 이퀄라이저를 갖춘 고용량 DRAM을 위한 컨트롤러 PHY 설계

학위논문 (박사) -- 서울대학교 대학원 : 공과대학 전기·정보공학부, 2020. 8. 김수환.A controller PHY for managed DRAM solution, which is a new memory structure to maximize capacity while minimizing refresh power, is presented. Inter-symbol interference is critical in such a high-capacity DRAM interface in which many DRAM chips share a command/address (C/A) channel. A pulse-based feed-forward equalizer (PB-FFE) is introduced to reduce ISI on a C/A channel. The controller PHY supports all the training sequences specified in the DDR4 standard. A glitch-free DCDL is also adopted to perform link training efficiently and to reduce training time. The DQ transmitter adopts quarter-rate architecture to reduce output latency. For the quarter-rate transmitters in DQ, we propose a quadrature error corrector (QEC), in which clock signal phase errors are corrected using two replicas of the 4:1 serializer of the output stage. Pulse shrinking is used to compare and equalize the outputs of these two replica serializers. A controller PHY was fabricated in 55nm CMOS. The PB-FFE increases the timing margin from 0.23UI to 0.29UI at 1067Mbps. At 2133Mbps, the read timing and voltage margins are 0.53UI and 211mV after read training, and the write margins are 0.72UI and 230mV after write training. To validate the QEC effectiveness, a prototype quarter-rate transmitter, including the QEC, was fabricated to another chip in 65nm CMOS. Adopting our QEC, the experimental results show that the output phase errors of the transmitter are reduced to a residual error of 0.8ps, and the output eye width and height are improved by 84% and 61%, respectively, at a data-rate of 12.8Gbps.본 연구에서 용량을 최대화하면서도 리프레시 전력을 최소화할 수 있는 새로운 메모리 구조인 관리형 DRAM 솔루션을 위한 컨트롤러 PHY를 제시하였다. 이와 같은 고용량 DRAM 인터페이스에서는 많은 DRAM 칩이 명령 / 주소 (C/A) 채널을 공유하고 있어서 심볼 간 간섭이 발생한다. 본 연구에서는 이러한 C/A 채널에서의 심볼 간 간섭을 줄이기 위해 펄스 기반 피드 포워드 이퀄라이저 (PB-FFE)를 채택하였다. 또한 본 연구의 컨트롤러 PHY는 DDR4 표준에 지정된 모든 트레이닝 시퀀스를 지원한다. 링크 트레이닝을 효율적으로 수행하고 트레이닝 시간을 줄이기 위해 글리치가 발생하지 않는 디지털 제어 지연 라인 (DCDL)을 채택하였다. 컨트롤러 PHY의 DQ 송신기는 출력 대기 시간을 줄이기 위해 쿼터 레이트 구조를 채택하였다. 쿼터 레이트 송신기의 경우에는 직교 클럭 간 위상 오류가 출력 신호의 무결성에 영향을 주게 된다. 이러한 영향을 최소화하기 위해 본 연구에서는 출력 단의 4 : 1 직렬 변환기의 두 복제본을 사용하여 클록 신호 위상 오류를 수정하는 QEC (Quadrature Error Corrector)를 제안하였다. 복제된 2개의 직렬 변환기의 출력을 비교하고 균등화하기 위해 펄스 수축 지연 라인이 사용되었다. 컨트롤러 PHY는 55nm CMOS 공정으로 제조되었다. PB-FFE는 1067Mbps에서 C/A 채널 타이밍 마진을 0.23UI에서 0.29UI로 증가시킨다. 읽기 트레이닝 후 읽기 타이밍 및 전압 마진은 2133Mbps에서 0.53UI 및 211mV이고, 쓰기 트레이닝 후 쓰기 마진은 0.72UI 및 230mV이다. QEC의 효과를 검증하기 위해 QEC를 포함한 프로토 타입 쿼터 레이트 송신기를 65nm CMOS의 다른 칩으로 제작하였다. QEC를 적용한 실험 결과, 송신기의 출력 위상 오류가 0.8ps의 잔류 오류로 감소하고, 출력 데이터 눈의 폭과 높이가 12.8Gbps의 데이터 속도에서 각각 84 %와 61 % 개선되었음을 보여준다.CHAPTER 1 INTRODUCTION 1 1.1 MOTIVATION 1 1.1.1 HEAVY LOAD C/A CHANNEL 5 1.1.2 QUARTER-RATE ARCHITECTURE IN DQ TRANSMITTER 7 1.1.3 SUMMARY 8 1.2 THESIS ORGANIZATION 10 CHAPTER 2 ARCHITECTURE 11 2.1 MDS DIMM STRUCTURE 11 2.2 MDS CONTROLLER 15 2.3 MDS CONTROLLER PHY 17 2.3.1 INITIALIZATION SEQUENCE 20 2.3.2 LINK TRAINING FINITE-STATE MACHINE 23 2.3.3 POWER DOWN MODE 28 CHAPTER 3 PULSE-BASED FEED-FORWARD EQUALIZER 29 3.1 COMMAND/ADDRESS CHANNEL 29 3.2 COMMAND/ADDRESS TRANSMITTER 33 3.3 PULSE-BASED FEED-FORWARD EQUALIZER 35 CHAPTER 4 CIRCUIT IMPLEMENTATION 39 4.1 BUILDING BLOCKS 39 4.1.1 ALL-DIGITAL PHASE-LOCKED LOOP (ADPLL) 39 4.1.2 ALL-DIGITAL DELAY-LOCKED LOOP (ADDLL) 44 4.1.3 GLITCH-FREE DCDL CONTROL 47 4.1.4 DUTY-CYCLE CORRECTOR (DCC) 50 4.1.5 DQ/DQS TRANSMITTER 52 4.1.6 DQ/DQS RECEIVER 54 4.1.7 ZQ CALIBRATION 56 4.2 MODELING AND VERIFICATION OF LINK TRAINING 59 4.3 BUILT-IN SELF-TEST CIRCUITS 66 CHAPTER 5 QUADRATURE ERROR CORRECTOR USING REPLICA SERIALIZERS AND PULSE-SHRINKING DELAY LINES 69 5.1 PHASE CORRECTION USING REPLICA SERIALIZERS AND PULSE-SHRINKING UNITS 69 5.2 OVERALL QEC ARCHITECTURE AND ITS OPERATION 71 5.3 FINE DELAY UNIT IN THE PSDL 76 CHAPTER 6 EXPERIMENTAL RESULTS 78 6.1 CONTROLLER PHY 78 6.2 PROTOTYPE QEC 88 CHAPTER 7 CONCLUSION 94 BIBLIOGRAPHY 96Docto

NEPP Update of Independent Single Event Upset Field Programmable Gate Array Testing

This presentation provides a NASA Electronic Parts and Packaging (NEPP) Program update of independent Single Event Upset (SEU) Field Programmable Gate Array (FPGA) testing including FPGA test guidelines, Microsemi RTG4 heavy-ion results, Xilinx Kintex-UltraScale heavy-ion results, Xilinx UltraScale+ single event effect (SEE) test plans, development of a new methodology for characterizing SEU system response, and NEPP involvement with FPGA security and trust

High-speed, low cost test platform using FPGA technology

The object of this research is to develop a low-cost, adaptable testing platform for multi-GHz digital applications, with concentration on the test requirement of advanced devices. Since most advanced ATEs are very expensive, this equipment is not always available for testing cost-sensitive devices. The approach is to use recently-introduced advanced FPGAs for the core logic of the testing platform, thereby allowing for a low-cost, low power-consumption, high-performance, and adaptable test system. Furthermore to customize the testing system for specific applications, we implemented multiple extension testing modules base on this platform. With these extension modules, new functions can be added easily and the test system can be upgraded with specific features required for other testing purposes. The applications of this platform can help those digital devices to be delivered into market with shorter time, lower cost and help the development of the whole industry.Ph.D

비디오 클럭 주파수 보상 구조를 이용한 디스플레이포트 수신단 설계

학위논문 (박사)-- 서울대학교 대학원 : 전기·컴퓨터공학부, 2014. 8. 정덕균.This thesis presents the design of DisplayPort receiver which is a high speed digital display interface replacing existing interfaces such as DVI, HDMI, LVDS and so on. The two prototype chips are fabricated, one is a 5.4/2.7/1.62-Gb/s multi-rate DisplayPort receiver and the other is a 2.7/1.62-Gb/s multi-rate Embedded DisplayPort (eDP) receiver for an intra-panel display interface. The first receiver which is designed to support the external box-to-box display connection provides up to 4K resolution (4096×2160) with the maximum data rate of 21.6 Gb/s when 4 lanes are all used. The second one aims to connect internal chip-to-chip connection such as graphic processors to display panels in notebooks or tablet PCs. It supports the maximum data rate of 10.8 Gb/s with 4-lane operation which is able to provide the resolution of WQXGA (2560×1600). Since there is no dedicated clock channel, it must contain clock and data recovery (CDR) circuit to extract the link clock from the data stream. All-Digital CDR (ADCDR) is adopted for area efficiency and better performances of the multi-rate operation. The link rate is fixed but the video clock frequency range is fairly wide for supporting all display resolutions and frame rates. Thus, the wide range video clock frequency synthesizer is essential for reconstructing the transmitted video data. A source device starts link training before transmitting video data to recover the clock and establish the link. When the loss of synchronization between the source device and the sink device happens, it usually restarts the link training and try to re-establish the link. Since link training spends several milliseconds for initializing, the video image is not displayed properly in the sink device during this interval. The proposed clock recovery scheme can significantly shorten the time to recover from the link failure with the ADCDR topology. Once the link is established after link training, the ADCDR memorizes the DCO codes of the synchronization state and when the loss of synchronization happens, it restores the previous DCO code so that the clock is quickly recovered from the failure state without the link re-training. The direct all-digital frequency synthesizer is proposed to generate the cycle-accurate video clock frequency. The video clock frequency has wide range to cover all display formats and is determined by the division ratio of large M and N values. The proposed frequency synthesizer using a programmable integer divider and a multi-phase switching fractional divider with the delta-sigma modulation exhibits better performances and reduces the design complexity operating with the existing clock from the ADCDR circuit. In asynchronous clock system, the transmitted M value which changes over time is measured by using a counter running with the long reference period (N cycles) and updated once per blank period. Thus, the transmitted M is not accurate due to its low update rate, transport latency and quantization error. The proposed frequency error compensation scheme resolves these problems by monitoring the status of FIFO between the clock domains. The first prototype chip is fabricated in a 65-nm CMOS process and the physical layer occupies 1.39 mm2 and the estimated area of the link layer is 2.26 mm2. The physical layer dissipates 86/101/116 mW at 1.62/2.7/5.4 Gb/s data rate with all 4-lane operation. The power consumption of the link layer is 107/145/167 mW at 1.62/2.7/5.4 Gb/s. The second prototype chip, fabricated in a 0.13μm CMOS process, presents the physical layer area of 1.59 mm2 and the link layer area of 3.01 mm2. The physical layer dissipates 21 mW at 1.62 Gb/s and 29 mW at 2.7 Gb/s with 2-lane operation. The power consumption of the link layer is 31 mW at 1.62 Gb/s and 41 mW at 2.7 Gb/s with 2-lane operation. The core area of the video clock synthesizer occupies 0.04 mm2 and the power dissipation is 5.5 mW at a low bit rate and 9.1 mW at a high bit rate. The output frequency range is 25 to 330 MHz.ABSTRACT I CONTENTS IV LIST OF FIGURES VII LIST OF TABLES XII CHAPTER 1 INTRODUCTION 1 1.1 BACKGROUND 1 1.2 MOTIVATION 4 1.3 THESIS ORGANIZATION 12 CHAPTER 2 DIGITAL DISPLAY INTERFACE 13 2.1 OVERVIEW 13 2.2 DISPLAYPORT INTERFACE CHARACTERISTICS 18 2.2.1 DISPLAYPORT VERSION 1.2 18 2.2.2 EMBEDDED DISPLAYPORT VERSION 1.2 21 2.3 DISPLAYPORT INTERFACE ARCHITECTURE 23 2.3.1 LAYERED ARCHITECTURE 23 2.3.2 MAIN STREAM PROTOCOL 27 2.3.3 INITIALIZATION AND LINK TRAINING 30 2.3.3 VIDEO STREAM CLOCK RECOVERY 35 CHAPTER 3 DESIGN OF DISPLAYPORT RECEIVER 39 3.1 OVERVIEW 39 3.2 PHYSICAL LAYER 43 3.3 LINK LAYER 55 3.3.1 OVERALL ARCHITECTURE 55 3.3.2 AUX CHANNEL 58 3.3.3 VIDEO TIMING GENERATION 61 3.3.4 CONTENT PROTECTION 63 3.3.5 AUDIO TRANSMISSION 66 3.4 EXPERIMENTAL RESULTS 68 CHAPTER 4 DESIGN OF EMBEDDED DISPLAYPORT RECEIVER 81 4.1 OVERVIEW 81 4.2 PHYSICAL LAYER 84 4.3 LINK LAYER 88 4.3.1 OVERALL ARCHITECTURE 88 4.3.2 MAIN LINK STREAM 90 4.3.3 CONTENT PROTECTION 93 4.4 PROPOSED CLOCK RECOVERY SCHEME 94 4.5 EXPERIMENTAL RESULTS 100 CHAPTER 5 PROPOSED VIDEO CLOCK SYNTHESIZER AND FREQUENCY CONTROL SCHEME 113 5.1 MOTIVATION 113 5.2 PROPOSED VIDEO CLOCK SYNTHESIZER 115 5.3 BUILDING BLOCKS 121 5.4 FREQUENCY ERROR COMPENSATION 126 5.5 EXPERIMENTAL RESULTS 131 CHAPTER 6 CONCLUSION 138 BIBLIOGRAPHY 141 초 록 152Docto