대역폭 증대 기술을 이용한 전력 효율적 고속 송신 시스템 설계

학위논문(박사) -- 서울대학교대학원 : 공과대학 전기·정보공학부, 2022.2. 정덕균.The high-speed interconnect at the datacenter is being more crucial as 400 Gb Ethernet standards are developed. At the high data rate, channel loss re-quires bandwidth extension techniques for transmitters, even for short-reach channels. On the other hand, as the importance of east-to-west connection is rising, the data center architectures are switching to spine-leaf from traditional ones. In this trend, the number of short-reach optical interconnect is expected to be dominant. The vertical-cavity surface-emitting laser (VCSEL) is a com-monly used optical modulator for short-reach interconnect. However, since VCSEL has low bandwidth and nonlinearity, the optical transmitter also needs bandwidth-increasing techniques. Additionally, the power consumption of data centers reaches a point of concern to affect climate change. Therefore, this the-sis focuses on high-speed, power-efficient transmitters for data center applica-tions. Before the presenting circuit design, bandwidth extension techniques such as fractionally-spaced feed-forward equalizer (FFE), on-chip transmission line, inductive peaking, and T-coil are mathematically analyzed for their effec-tiveness. For the first chip, a power and area-efficient pulse-amplitude modulation 4 (PAM-4) transmitter using 3-tap FFE based on a slow-wave transmission line is presented. A passive delay line is adopted for generating an equalizer tap to overcome the high clocking power consumption. The transmission line achieves a high slow-wave factor of 15 with double floating metal shields around the differential coplanar waveguide. The transmitter includes 4:1 multi-plexers (MUXs) and a quadrature clock generator for high-speed data genera-tion in a quarter-rate system. The 4:1 MUX utilizes a 2-UI pulse generator, and the input configuration is determined by qualitative analysis. The chip is fabri-cated in 65 nm CMOS technology and occupies an area of 0.151 mm2. The proposed transmitter system exhibits an energy efficiency of 3.03 pJ/b at the data rate of 48 Gb/s with PAM-4 signaling. The second chip presents a power-efficient PAM-4 VCSEL transmitter using 3-tap FFE and negative-k T-coil. The phase interpolators (PIs) generate frac-tionally-spaced FFE tap and correct quadrature phase error. The PAM-4 com-bining 8:1 MUX is proposed rather than combining at output driver with double 4:1 MUXs to reduce serializing power consumption. T-coils at the internal and output node increase the bandwidth and remove inter-symbol interference (ISI). The negative-k T-coil at the output network increases the bandwidth 1.61 times than without T-coil. The VCSEL driver is placed on the high VSS domain for anode driving and power reduction. The chip is fabricated in 40 nm CMOS technology. The proposed VCSEL transmitter operates up to 48 Gb/s NRZ and 64 Gb/s PAM-4 with the power efficiency of 3.03 pJ/b and 2.09 pJ/b, respec-tively.400Gb 이더넷 표준이 개발됨에 따라 데이터 센터의 고속 상호 연결이 더욱 중요해지고 있다. 높은 데이터 속도에서의 채널 손실에 의해 단거리 채널의 경우에도 송신기에 대한 대역폭 확장 기술이 필요하다. 한편, 데이터 센터 내 동-서 연결의 중요성이 높아지면서 데이터 센터 아키텍처가 기존의 아키텍처에서 스파인-리프로 전환되고 있다. 이러한 추세에서 단거리 광학 인터커넥트의 수가 점차 우세해질 것으로 예상된다. 수직 캐비티 표면 방출 레이저(VCSEL)는 일반적으로 단거리 상호 연결을 위해 사용되는 광학 모듈레이터이다. VCSEL은 낮은 대역폭과 비선형성을 가지고 있기 때문에, 광 송신기도 대역폭 증가 기술을 필요로 한다. 또한, 데이터 센터의 전력 소비는 기후 변화에 영향을 미칠 수 있는 우려 지점에 도달했다. 따라서, 본 논문은 데이터 센터 응용을 위한 고속 전력 효율적인 송신기에 초점을 맞추고 있다. 회로 설계를 제시하기 전에, 부분 간격 피드-포워드 이퀄라이저 (FFE), 온칩 전송선로, 인덕터, T-코일과 같은 대역폭 확장 기술을 수학적으로 분석한다. 첫 번째 칩은 저속파 전송선로를 기반으로 한 3-탭 FFE를 사용하는 전력 및 면적 효율적인 펄스-진폭-변조 4(PAM-4) 송신기를 제시한다. 높은 클럭 전력 소비를 극복하기 위해 이퀄라이저 탭 생성을 위해 수동소자 지연 라인을 채택했다. 전송 라인은 차동 동일평면도파관 주위에 이중 플로팅 금속 차폐를 사용하여 15의 높은 전달속도 감쇠를 달성한다. 송신기에는 4:1 멀티플렉서(MUX)와 4-위상 클럭 생성기가 포함되어 있다. 4:1 MUX는 2-UI 펄스 발생기를 사용하며, 정성 분석에 의해 입력 구성이 결정된다. 이 칩은 65 nm CMOS 기술로 제작되었으며 0.151 mm2의 면적을 차지한다. 제안된 송신기 시스템은 PAM-4 신호와 함께 48 Gb/s의 데이터 속도에서 3.03 pJ/b의 에너지 효율을 보여준다. 두 번째 칩에서는 3-탭 FFE 및 역회전 T-코일을 사용하는 전력 효율적인 PAM-4 VCSEL 송신기를 제시한다. 위상 보간기(PI)는 부분 간격 FFE 탭을 생성하고 4-위상 클럭 오류를 수정하는 데 사용된다. 직렬화 전력 소비를 줄이기 위해 출력 드라이버에서 MSB와 LSB를 두 개의 4:1 MUX를 통해 결합하는 대신 8:1 MUX를 통해 PAM-4로 결합하는 회로가 제안된다. 내부 및 출력 노드에서 T-코일은 대역폭을 증가시키고 기호 간 간섭(ISI)을 제거한다. 출력 네트워크에서 역회전 T-코일은 T-코일이 없는 경우보다 대역폭을 1.61배 증가시킨다. VCSEL 드라이버는 양극 구동 및 전력 감소를 위해 높은 VSS 도메인에 배치된다. 이 칩은 40 nm CMOS 기술로 제작되었다. 제안된 VCSEL 송신기는 각각 3.03pJ/b와 2.09pJ/b의 전력 효율로 최대 48Gb/s NRZ와 64Gb/s PAM-4까지 작동한다.ABSTRACT I CONTENTS III LIST OF FIGURES V LIST OF TABLES IX CHAPTER 1 INTRODUCTION 1 1.1 MOTIVATION 1 1.2 THESIS ORGANIZATION 5 CHAPTER 2 BACKGROUND OF HIGH-SPEED INTERFACE 6 2.1 OVERVIEW 6 2.2 BASIS OF DATA CENTER ARCHITECTURE 9 2.3 SHORT-REACH INTERFACE STANDARDS 12 2.4 ANALYSES OF BANDWIDTH EXTENSION TECHNIQUES 16 2.4.1 FRACTIONALLY-SPACED FFE 16 2.4.2 TRANSMISSION LINE 21 2.4.3 INDUCTOR 24 2.4.4 T-COIL 33 CHAPTER 3 DESIGN OF 48 GB/S PAM-4 ELECTRICAL TRANSMITTER IN 65 NM CMOS 43 3.1 OVERVIEW 43 3.2 FFE BASED ON DOUBLE-SHIELDED COPLANAR WAVEGUIDE 46 3.2.1 BASIC CONCEPT 46 3.2.2 PROPOSED DOUBLE-SHIELDED COPLANAR WAVEGUIDE 47 3.3 DESIGN CONSIDERATION ON 4:1 MUX 50 3.4 PROPOSED PAM-4 ELECTRICAL TRANSMITTER 53 3.5 MEASUREMENT 57 CHAPTER 4 DESIGN OF 64 GB/S PAM-4 OPTICAL TRANSMITTER IN 40 NM CMOS 64 4.1 OVERVIEW 64 4.2 DESIGN CONSIDERATION OF OPTICAL TRANSMITTER 66 4.3 PROPOSED PAM-4 VCSEL TRANSMITTER 69 4.4 MEASUREMENT 82 CHAPTER 5 CONCLUSIONS 88 BIBLIOGRAPHY 90 초 록 101박

Detectors and cryostat design for the SuMIRe Prime Focus Spectrograph (PFS)

We describe the conceptual design of the camera cryostats, detectors, and detector readout electronics for the SuMIRe Prime Focus Spectrograph (PFS) being developed for the Subaru telescope. The SuMIRe PFS will consist of four identical spectrographs, each receiving 600 fibers from a 2400 fiber robotic positioner at the prime focus. Each spectrograph will have three channels covering wavelength ranges 3800 {\AA} - 6700 {\AA}, 6500 {\AA} - 10000 {\AA}, and 9700 {\AA} - 13000 {\AA}, with the dispersed light being imaged in each channel by a f/1.10 vacuum Schmidt camera. In the blue and red channels a pair of Hamamatsu 2K x 4K edge-buttable CCDs with 15 um pixels are used to form a 4K x 4K array. For the IR channel, the new Teledyne 4K x 4K, 15 um pixel, mercury-cadmium-telluride sensor with substrate removed for short-wavelength response and a 1.7 um cutoff will be used. Identical detector geometry and a nearly identical optical design allow for a common cryostat design with the only notable difference being the need for a cold radiation shield in the IR camera to mitigate thermal background. This paper describes the details of the cryostat design and cooling scheme, relevant thermal considerations and analysis, and discusses the detectors and detector readout electronics

Management, Optimization and Evolution of the LHCb Online Network

The LHCb experiment is one of the four large particle detectors running at the Large Hadron Collider (LHC) at CERN. It is a forward single-arm spectrometer dedicated to test the Standard Model through precision measurements of Charge-Parity (CP) violation and rare decays in the b quark sector. The LHCb experiment will operate at a luminosity of 2x10^32cm-2s-1, the proton-proton bunch crossings rate will be approximately 10 MHz. To select the interesting events, a two-level trigger scheme is applied: the rst level trigger (L0) and the high level trigger (HLT). The L0 trigger is implemented in custom hardware, while HLT is implemented in software runs on the CPUs of the Event Filter Farm (EFF). The L0 trigger rate is dened at about 1 MHz, and the event size for each event is about 35 kByte. It is a serious challenge to handle the resulting data rate (35 GByte/s). The Online system is a key part of the LHCb experiment, providing all the IT services. It consists of three major components: the Data Acquisition (DAQ) system, the Timing and Fast Control (TFC) system and the Experiment Control System (ECS). To provide the services, two large dedicated networks based on Gigabit Ethernet are deployed: one for DAQ and another one for ECS, which are referred to Online network in general. A large network needs sophisticated monitoring for its successful operation. Commercial network management systems are quite expensive and dicult to integrate into the LHCb ECS. A custom network monitoring system has been implemented based on a Supervisory Control And Data Acquisition (SCADA) system called PVSS which is used by LHCb ECS. It is a homogeneous part of the LHCb ECS. In this thesis, it is demonstrated how a large scale network can be monitored and managed using tools originally made for industrial supervisory control. The thesis is organized as the follows: Chapter 1 gives a brief introduction to LHC and the B physics on LHC, then describes all sub-detectors and the trigger and DAQ system of LHCb from structure to performance. Chapter 2 first introduces the LHCb Online system and the dataflow, then focuses on the Online network design and its optimization. In Chapter 3, the SCADA system PVSS is introduced briefly, then the architecture and implementation of the network monitoring system are described in detail, including the front-end processes, the data communication and the supervisory layer. Chapter 4 first discusses the packet sampling theory and one of the packet sampling mechanisms: sFlow, then demonstrates the applications of sFlow for the network trouble-shooting, the traffic monitoring and the anomaly detection. In Chapter 5, the upgrade of LHC and LHCb is introduced, the possible architecture of DAQ is discussed, and two candidate internetworking technologies (high speed Ethernet and InfniBand) are compared in different aspects for DAQ. Three schemes based on 10 Gigabit Ethernet are presented and studied. Chapter 6 is a general summary of the thesis

Pluggable Optical Connector Interfaces for Electro-Optical Circuit Boards

A study is hereby presented on system embedded photonic interconnect technologies, which would address the communications bottleneck in modern exascale data centre systems driven by exponentially rising consumption of digital information and the associated complexity of intra-data centre network management along with dwindling data storage capacities. It is proposed that this bottleneck be addressed by adopting within the system electro-optical printed circuit boards (OPCBs), on which conventional electrical layers provide power distribution and static or low speed signaling, but high speed signals are conveyed by optical channels on separate embedded optical layers. One crucial prerequisite towards adopting OPCBs in modern data storage and switch systems is a reliable method of optically connecting peripheral cards and devices within the system to an OPCB backplane or motherboard in a pluggable manner. However the large mechanical misalignment tolerances between connecting cards and devices inherent to such systems are contrasted by the small sizes of optical waveguides required to support optical communication at the speeds defined by prevailing communication protocols. An innovative approach is therefore required to decouple the contrasting mechanical tolerances in the electrical and optical domains in the system in order to enable reliable pluggable optical connectivity. This thesis presents the design, development and characterisation of a suite of new optical waveguide connector interface solutions for electro-optical printed circuit boards (OPCBs) based on embedded planar polymer waveguides and planar glass waveguides. The technologies described include waveguide receptacles allowing parallel fibre connectors to be connected directly to OPCB embedded planar waveguides and board-to-board connectors with embedded parallel optical transceivers allowing daughtercards to be orthogonally connected to an OPCB backplane. For OPCBs based on embedded planar polymer waveguides and embedded planar glass waveguides, a complete demonstration platform was designed and developed to evaluate the connector interfaces and the associated embedded optical interconnect. Furthermore a large portfolio of intellectual property comprising 19 patents and patent applications was generated during the course of this study, spanning the field of OPCBs, optical waveguides, optical connectors, optical assembly and system embedded optical interconnects

Multilevel Modulation and Transmission in VCSEL-based Short-range Fiber Optic Links

As the demand for ever higher throughput short-range optical links is growing, research and industry associations have shown increased interest in multilevel modulation formats, such as the four leveled pulse amplitude modulation, referred to as 4-PAM. As on-off keying (OOK) persists to be the choice for low latency applications, for example high performance computing, datacenter operators see 4-PAM as the next format to succeed current OOK-based optical interconnects. Throughput can be increased in many ways: parallel links can be deployed, multicore fibers can be used or more efficient modulation formats with digital signal processing is an alternative. Therefore, to improve link data rates, the introduction of new modulation formats and pre-emphasis are primarily considered in this thesis. In a bandwidth-limited link, turning towards spectrally efficient formats is one of the methods to\ua0 overcome the bandwidth requirements of OOK. Such are the considerations when opting for 3-PAM or 4-PAM schemes. Both require lower bandwidth than OOK and are potential candidates in such scenarios. 4-PAM provides double spectral efficiency and double data rate at the same symbol rate as on-off keying, but, as with any technology transition, new challenges emerge, such as a higher SNR requirement, a lower tolerance to VCSEL nonlinearities and skewing of the signal in the time domain. 3-PAM could potentially be an in-between solution, as it requires 33% less bandwidth than OOK and is less sensitive to VCSEL dynamics which could impair the transmission. A study is presented where 3-PAM has outperformed both OOK and 4-PAM in the same link. Detailed investigation of legacy 25G class VCSELs has shown that devices with moderate damping are suitable for the transition to 4-PAM. The pre-emphasis of signals is a powerful tool to increase link bandwidth at the cost of modulation amplitude. This has been investigated in this thesis for on-offkeying and has shown 9% and 27% increase in bit rate for error-free operation with two pre-emphasis approaches. Similarly, pre-emphasis of a 4-PAM electrical signals has enabled 71.8 Gbps transmission back-to-back with lightweight forward error correction and 94 Gbps net data rate was achieved with the same pre-emphasis and post-processing using an offline least-mean-square equalizer

High-speed low-power modulator driver arrays for medium-reach optical networks

The internet is becoming the ubiquitous tool that is changing the lives of so many citizens across the world. Commerce, government, industry, healthcare and social interactions are all increasingly using internet applications to improve and facilitate communications. This is especially true for videoenabled applications, which currently demand much higher data rates and quality from data networks. High definition TV streaming services are emerging and these again will significantly push the demand for widely deployed, high-bandwidth services. The current access passive optical networks (PONs) use a single wavelength for downstream transmission and a separate one for upstream transmission. Incorporating wavelength-division multiplexing (WDM) in a PON allows for much higher bandwidths in both directions. While WDM technologies have been successfully deployed for many years in metro and core networks, in access networks they are not commonly used yet. This is mainly due to the high costs associated with deploying entire WDM access networks. However, the present optical networks cannot be simply and cost-effectively scaled to provide the capacity for tomorrow’s users. As an effect there is a strong need for new WDM access components which are compact, cost-competitive and mass-manufacturable. Increasing the number of wavelengths for WDM-PON automatically leads to an increase in the number of single pluggable transceivers, which brings substantial design challenges and additional costs. The multitude of TXs and RXs for different wavelength channels increases the total footprint considerably. Photonic integration of transceivers into arrays will significantly reduce the footprint and cost. However, the total power consumption of an array device is an issue. To avoid the use of a thermoelectric cooler, the integration density of components is severely limited by the heat dissipating capabilities offered by their package. As a result the WDM-PON philosophy necessitates the reduction of the transceiver’s power dissipation. From this plea it is apparent that the main technology challenges for realizing future-proof optical (access) networks are reducing active component power consumption, shrinking form factors and lowering assembly costs. In this perspective an over 100 Gb/s throughput component, composed of 10 channels at 11.3 Gb/s per wavelength channel would be a great contribution to the expansion of customer bandwidth. It can provide increased line rates to the end users at speeds of 10 Gb/s per wavelength. As RXs typically consume much less power than externally modulated TXs, they can relatively easily be integrated into an array. Mainly high speed optical transmitters have significant power consumptions and the heat generation caused by power dissipation forms a critical obstacle in the development of a 10-channel transmitter, which again underlines the importance of power reduction. Alongside the introduction of WDM in access networks, also inter-office point-to-point connections in data center environments could benefit from the WDM philosophy. As data center operators often suffer from fiber scarcity or do not own their fiber infrastructure, WDM technologies are essential to deliver reach and capacity extension for these scenarios. Interdata center communication also benefits from cost-, footprint- and energyefficient components operating at high speed to maximize the throughput. As an effect integrated over 100 Gb/s transceivers, such as 4 channels at 28 Gb/s, are highly desirable. The research described in this dissertation was partly funded by the European FP7 ICT project C3PO (Colourless and Coolerless Components for low Power Optical Networks) and the UGent special research fund. The C3PO project aimed to develop a new generation of green Si-photonic compatible components with record low power consumption, that can enable bandwidth growth and constrain the total cost. C3PO envisioned building high-capacity access networks employing reflective photonic components. To achieve this, cost-competitive reflective transmitters based on electroabsorption modulators (EAM) needed to be closely integrated into arrays. A multi-wavelength optical source provides the required wavelength channels for both downstream and upstream signals in the WDM-PON. Chapter 1 gives a short overview of a PON and describes the main implementations of a WDM-PON access network. It introduces integrated low power transmitter arrays for a cost-effective architecture of WDM-PONs and inter-data center communication. Chapter 2 compares different optical transmitters and gives a short overview of their most important characteristics. External modulation through both Mach-Zehnder modulators (MZMs) and EAMs is described. It shows that EAMs are the best choice for low power transmitter array integration, thanks to their lower drive voltage and smaller form factor, compared to MZMs. To achieve a reduced consumption, the electronic modulator driver topology is studied in chapter 3. The challenge in designing modulator drivers is the need to deliver very large currents in combination with high voltage swings. Four distinct output configurations are compared and techniques to reduce the power consumption of the drivers are described. Chapter 5 presents duobinary (DB), a modulation scheme that is gaining interest in today’s optical transmission. As the required bandwidth is about half that of NRZ, it softens the constraints on the transmitter bandwidth. Thanks to its narrow optical spectrum, it has an improved tolerance to dispersion in long haul single mode links and it can improve the spectral efficiency in WDM architectures. For optical DB a precoder is necessary to assure the received signal is equal to the original binary signal. The conducted research that resulted in this dissertation produced 2 low power EAM driver arrays: A 10-channel 113 Gb/s modulator driver array with state-of-the art ultra-low power consumption. A 2-channel 56 Gb/s duobinary driver array with a differential output with low power consumption. Both designs are elaborately analyzed in chapter 4 and 6 respectively. To the best of our knowledge the 10-channel EAM driver array is the first in its kind, while achieving the lowest power consumption for an EAM driver so far reported, 50% below the state of the art in power consumption. The 2-channel EAM driver array is the fastest modulator driver including on-chip duobinary encoding and precoding reported so far. The final chapter provides an overview of the foremost conclusions from the presented research. It is concluded with suggestions for further research

Roadmap of optical communications

© 2016 IOP Publishing Ltd. Lightwave communications is a necessity for the information age. Optical links provide enormous bandwidth, and the optical fiber is the only medium that can meet the modern society's needs for transporting massive amounts of data over long distances. Applications range from global high-capacity networks, which constitute the backbone of the internet, to the massively parallel interconnects that provide data connectivity inside datacenters and supercomputers. Optical communications is a diverse and rapidly changing field, where experts in photonics, communications, electronics, and signal processing work side by side to meet the ever-increasing demands for higher capacity, lower cost, and lower energy consumption, while adapting the system design to novel services and technologies. Due to the interdisciplinary nature of this rich research field, Journal of Optics has invited 16 researchers, each a world-leading expert in their respective subfields, to contribute a section to this invited review article, summarizing their views on state-of-the-art and future developments in optical communications