Design Techniques for High Pin Efficiency Wireline Transceivers

While the majority of wireline research investigates bandwidth improvement and how to overcome the high channel loss, pin efficiency is also critical in high-performance wireline applications. This dissertation proposes two different implementations for high pin efficiency wireline transceivers. The first prototype achieves twice pin efficiency than unidirectional signaling, which is 32Gb/s simultaneous bidirectional transceiver supporting transmission and reception on the same channel at the same time. It includes an efficient low-swing voltage-mode driver with an R-gm hybrid for signal separation, combining the continuous-time-linear-equalizer (CTLE) and echo cancellation (EC) in a single stage, and employing a low-complexity 5/4X CDA system. Support of a wide range of channels is possible with foreground adaptation of the EC finite impulse response (FIR) filter taps with a sign-sign least-mean-square (SSLMS) algorithm. Fabricated in TSMC 28-nm CMOS, the 32Gb/s SBD transceiver occupies $0.09 mm^{2}$ area and achieves 16Gb/s uni-directional and 32Gb/s simultaneous bi-directional signals. 32Gb/s SBD operation consumes 1.83mW/Gb/s with 10.8dB channel loss at Nyquist rate. The second prototype presents an optical transmitter with a quantum-dot (QD) microring laser. This can support wavelength-division multiplexing allowing for high pin efficiency application by packing multiple high-bandwidth signals onto one optical channel. The development QD microring laser model accurately captures the intrinsic photonic high-speed dynamics and allows for the future co-design of the circuits and photonic device. To achieve higher bandwidth than intrinsic one, utilizing both techniques of optical injection locking (OIL) and 2-tap asymmetric Feed-forward equalizer (FFE) can perform 22Gb/s operation with 3.2mW/Gb/s. The first hybrid-integration directly-modulated OIL QD microring laser system is demonstrated

차세대 자동차용 카메라 데이터 통신을 위한 비대칭 동시 양방향 송수신기의 설계

학위논문(박사) -- 서울대학교대학원 : 공과대학 전기·정보공학부, 2022.2. 정덕균.본 학위 논문에서는 차세대 자동차용 카메라 링크를 위해 높은 속도의 4레벨 펄스 진폭 변조 신호와 낮은 속도의 2레벨 펄스 진폭 변조 신호를 통신하는 비대칭 동시 양방향 송수신기의 설계 기술에 대해 제안하고 검증되었다. 첫번째 프로토타입 설계에서는, 10B6Q 직류 밸런스 코드를 탑재한 4레벨 펄스 진폭 변조 송신기와 고정된 데이터와 참조 레벨을 가지는 4레벨 펄스 진폭 변조 적응형 수신기에 대한 내용이 기술되었다. 4레벨 펄스 진폭 변조 송신기에서는 교류 연결 링크 시스템에 대응하기 위한 면적 및 전력 효율성이 좋은 10B6Q 코드가 제안되었다. 이 코드는 직류 밸런스를 맞추고 연속적으로 같은 심볼을 가지는 길이를 6개로 제한 시킨다. 비록 여기서는 입력 데이터 길이 10비트를 사용하였지만, 제안된 기술은 카메라의 다양한 데이터 타입에 대응할 수 있도록 입력 데이터 길이에 대한 확장성을 가진다. 반면, 4레벨 펄스 진폭 변조 적응형 수신기에서는, 샘플러의 옵셋을 최적으로 제거하여 더 낮은 비트에러율을 얻기 위해서, 기존의 데이터 및 참조 레벨을 조절하는 대신, 이 레벨들은 고정시키고 가변 게인 증폭기를 적응형으로 조절하도록 하였다. 상기 10B6Q 코드 및 고정 데이터 및 참조레벨 기술을 가진 프로토타입 칩들은 40 나노미터 상호보완형 메탈 산화 반도체 공정으로 제작되었고 칩 온 보드 형태로 평가되었다. 10B6Q 코드는 합성 게이트 숫자는 645개와 함께 단 0.0009 mm2 의 면적 만을 차지한다. 또한, 667 MHz 동작 주파수에서 단 0.23 mW 의 전력을 소모한다. 10B6Q 코드를 탑재한 송신기에서 8-Gb/s 4레벨 펄스 진폭 변조 신호를 고정 데이터 및 참조 레벨을 가지는 적응형 수신기로 12-m 케이블 (22-dB 채널 로스) 을 통해서 보낸 결과 최소 비트 에러율 108 을 달성하였고, 비트 에러율 105 에서는 아이 마진이 0.15 UI x 50 mV 보다 크게 측정되었다. 송수신기를 합친 전력 소모는 65.2 mW (PLL 제외) 이고, 성과의 대표수치는 0.37 pJ/b/dB 를 보여주었다. 첫번째 프로토타입 설계을 포함하여 개선된 두번째 프로토타입 설계에서는, 12-Gb/s 4레벨 펄스 진폭 변조 정방향 채널 신호와 125-Mb/s 2레벨 펄스 진폭 변조 역방향 채널 신호를 탑재한 비대칭 동시 양방향 송수신기에 대해 기술되고 검증되었다. 제안된 넓은 선형 범위를 가지는 하이브리드는 gmC 저대역 통과 필터와 에코 제거기와 함께 아웃바운드 신호를 24 dB 이상 효율적으로 감소시켰다. 또한, 넓은 선형 범위를 가지는 하이브리드와 함께 게인 감소기를 형성하게 되는 선형 범위 증폭기를 통해 4레벨 펄스 진폭 변조 신호의 선형성과 진폭의 트레이드 오프 관계를 깨는 것이 가능하였다. 동시 양방향 송수신기 칩은 40 나노미터 상호보완형 메탈 산화 반도체 공정으로 제작되었다. 상기 설계 기술들을 이용하여, 4레벨 펄스 진폭 변조 및 2레벨 펄스 진폭 변조 송수신기 모두 5m 채널 (채널 로스 15.9 dB) 에서 1E-12 보다 낮은 비트 에러율을 달성하였고, 총 78.4 mW 의 전력 소모를 기록하였다. 종합적인 송수신기는 성과 대표지표로 0.41 pJ/b/dB 와 함께 동시 양방향 통신 아래에서 4레벨 펄스 진폭 변조 신호 및 2레벨 펄스 진폭 변조 신호 각각에서 아이 마진 0.15 UI 와 0.57 UI 를 달성하였다. 이 수치는 성과 대표지표 0.5 이하를 가지는 기존 동시 양방향 송수신기와의 비교에서 최고의 아이 마진을 기록하였다.In this dissertation, design techniques of a highly asymmetric simultaneous bidirectional (SB) transceivers with high-speed PAM-4 and low-speed PAM-2 signals are proposed and demonstrated for the next-generation automotive camera link. In a first prototype design, a PAM-4 transmitter with 10B6Q DC balance code and a PAM-4 adaptive receiver with fixed data and threshold levels (dtLevs) are presented. In PAM-4 transmitter, an area- and power-efficient 10B6Q code for an AC coupled link system that guarantees DC balance and limited run length of six is proposed. Although the input data width of 10 bits is used here, the proposed scheme has an extensibility for the input data width to cover various data types of the camera. On the other hand, in the PAM-4 adaptive receiver, to optimally cancel the sampler offset for a lower BER, instead of adjusting dtLevs, the gain of a programmable gain amplifier is adjusted adaptively under fixed dtLevs. The prototype chips including above proposed 10B6Q code and fixed dtLevs are fabricated in 40-nm CMOS technology and tested in chip-on-board assembly. The 10B6Q code only occupies an active area of 0.0009 mm2 with a synthesized gate count of 645. It also consumes 0.23 mW at the operating clock frequency of 667 MHz. The transmitter with 10B6Q code delivers 8-Gb/s PAM-4 signal to the adaptive receiver using fixed dtLevs through a lossy 12-m cable (22-dB channel loss) with a BER of 1E-8, and the eye margin larger than 0.15 UI x 50 mV is measured for a BER of 1E-5. The proto-type chips consume 65.2 mW (excluding PLL), exhibiting an FoM of 0.37 pJ/b/dB. In a second prototype design advanced from the first prototypes, An asymmetric SB transceivers incorporating a 12-Gb/s PAM-4 forward channel and a 125-Mb/s PAM-2 back channel are presented and demonstrated. The proposed wide linear range (WLR) hybrid combined with a gmC low-pass filter and an echo canceller effectively suppresses the outbound signals by more than 24dB. In addition, linear range enhancer which forms a gain attenuator with WLR hybrid breaks the trade-off between the linearity and the amplitude of the PAM-4 signal. The SB transceiver chips are separately fabricated in 40-nm CMOS technology. Using above design techniques, both PAM-4 and PAM-2 SB transceivers achieve BER less than 1E-12 over a 5-m channel (15.9 dB channel loss), consuming 78.4 mW. The overall transceivers achieve an FoM of 0.41 pJ/b/dB and eye margin (at BER of 1E-12) of 0.15 UI and 0.57 UI for the forward PAM-4 and back PAM-2 signals, respectively, under SB communication. This is the best eye margin compared to the prior art SB transceivers with an FoM less than 0.5.CHAPTER 1 INTRODUCTION 1 1.1 MOTIVATION 1 1.2 DISSERTATION ORGANIZATION 4 CHAPTER 2 BACKGROUND ON AUTOMOTIVE CAMERA LINK 6 2.1 OVERVIEW 6 2.2 SYSTEM REQUIREMENTS 10 2.2.1 CHANNEL 10 2.2.2 POWER OVER DIFFERENTIAL LINE (PODL) 12 2.2.3 AC COUPLING AND DC BALANCE CODE 15 2.2.4 SIMULTANEOUS BIDIRECTIONAL COMMUNICATION 18 2.2.4.1 HYBRID 18 2.2.4.2 ECHO CANCELLER 20 2.2.5 ADAPTIVE RECEIVE EQUALIZATION 22 CHAPTER 3 AREA AND POWER EFFICIENT 10B6Q ENCODER FOR DC BALANCE 25 3.1 INTRODUCTION 25 3.2 PRIOR WORKS 28 3.3 PROPOSED AREA- AND POWER-EFFICIENT 10B6Q PAM-4 CODER 30 3.4 DESIGN OF THE 10B6Q CODE 33 3.4.1 PAM-4 DC BALANCE 35 3.4.2 PAM-4 TRANSITION DENSITY 35 3.4.3 10B6Q DECODER 37 3.5 IMPLEMENTATION AND MEASUREMENT RESULTS 40 CHAPTER 4 PAM-4 TRANSMITTER AND ADAPTIVE RECEIVER WITH FIXED DATA AND THRESHOLD LEVELS 45 4.1 INTRODUCTION 45 4.2 PRIOR WORKS 47 4.3 ARCHITECTURE AND IMPLEMENTATION 49 4.2.1 PAM-4 TRANSMITTER 49 4.2.2 PAM-4 ADAPTIVE RECEIVER 52 4.3 MEASUREMENT RESULTS 62 CHAPTER 5 ASYMMETRIC SIMULTANEOUS BIDIRECTIONAL TRANSCEIVERS USING WIDE LINEAR RANGE HYBRID 68 5.1 INTRODUCTION 68 5.2 PRIOR WORKS 70 5.3 WIDE LINEAR RANGE (WLR) HYBRID 75 5.3 IMPLEMENTATION 78 5.3.1 SERIALIZER (SER) DESIGN 78 5.3.2 DESERIALIZER (DES) DESIGN 79 5.4 HALF CIRCUIT ANALYSIS OF WLR HYBRID AND LRE 82 5.5 MEASUREMENT RESULTS 88 CHAPTER 6 CONCLUSION 97 BIBLIOGRAPHY 99 초 록 106박

State of the art in chip-to-chip interconnects

This thesis presents a study of short-range links for chips mounted in the same package, on printed circuit boards or interposers. Implemented in CMOS technology between 7 and 250 nm, with links that operate at a data rate between 0,4 and 112 Gb/s/pin and with energy efficiencies from 0,3 to 67,7 pJ/bit. The links operate on channels with an attenuation lower than 50 dB. A comparison is made with graphical representations between the different articles that shows the correlation between the different essential metrics of chip-to-chip interconnects, as well as its evolution over the last 20 years.Esta tesis presenta un estudio de enlaces de corto alcance para chips montados en un mismo paquete, en placas de circuito impreso o intercaladores. Implementado en tecnología CMOS entre 7 y 250 nm, con enlaces que operan a una velocidad de datos entre 0,4 y 112 Gb/s/pin y con eficiencias energéticas de 0,3 a 67,7 pJ/bit. Los enlaces operan en canales con una atenuación inferior a 50 dB. Se realiza una comparación con representaciones gráficas entre los diferentes artículos que muestra la correlación entre las distintas métricas esenciales de las interconexiones chip a chip, así como su evolución en los últimos 20 años.Aquesta tesi presenta un estudi d'enllaços de curt abast per a xips muntats en el mateix paquet, en plaques de circuits impresos o interposers. Implementat en tecnologia CMOS entre 7 i 250 nm, amb enllaços que funcionen a una velocitat de dades entre 0,4 i 112 Gb/s/pin i amb eficiències energètiques de 0,3 a 67,7 pJ/bit. Els enllaços funcionen en canals amb una atenuació inferior a 50 dB. Es fa una comparació amb representacions gràfiques entre els diferents articles que mostra la correlació entre les diferents mètriques essencials d'interconnexions xip a xip, així com la seva evolució en els darrers 20 anys

Visible Light Communication (VLC)

Visible light communication (VLC) using light-emitting diodes (LEDs) or laser diodes (LDs) has been envisioned as one of the key enabling technologies for 6G and Internet of Things (IoT) systems, owing to its appealing advantages, including abundant and unregulated spectrum resources, no electromagnetic interference (EMI) radiation and high security. However, despite its many advantages, VLC faces several technical challenges, such as the limited bandwidth and severe nonlinearity of opto-electronic devices, link blockage and user mobility. Therefore, significant efforts are needed from the global VLC community to develop VLC technology further. This Special Issue, “Visible Light Communication (VLC)”, provides an opportunity for global researchers to share their new ideas and cutting-edge techniques to address the above-mentioned challenges. The 16 papers published in this Special Issue represent the fascinating progress of VLC in various contexts, including general indoor and underwater scenarios, and the emerging application of machine learning/artificial intelligence (ML/AI) techniques in VLC

Power control for WCDMA

This project tries to introduce itself in the physical implementations that make possible the denominated third generation mobile technology. As well as to know the technology kind that makes possible, for example, a video-call in real time. During this project, the different phases passed from the election of WCDMA like the access method for UMTS will appear. Its coexistence with previous network GSM will be analyzed, where the compatibility between systems has been one of the most important aspects in the development of WCDMA, the involved standardization organisms in the process, as well as the different protocols that make the mobile communications within a network UTRAN possible. Special emphasis during the study of the great contribution that has offered WCDMA with respect to the control of power of the existing signals will be made. The future lines that are considered in the present, and other comment that already are in their last phase of development in the field of the mobile technology. UMTS through WCDMA can be summarized like a revolution of the air interface accompanied by a revolution in the network of their architecture

Time and Frequency Transfer in a Coherent Multistatic Radar using a White Rabbit Network

Networks of coherent multistatic radars require accurate and stable time and frequency transfer (TFT) for range and Doppler estimation. TFT techniques based on global navigation satellite systems (GNSS), have been favoured for several reasons, such as enabling node mobility through wireless operation, geospatial referencing, and atomic clock level time and frequency stability. However, such systems are liable to GNSS-denial, where the GNSS carrier is temporarily or permanently removed. A denial-resilient system should consider alternative TFT techniques, such as the White Rabbit (WR) project. WR is an Ethernet based protocol, that is able to synchronise thousands of nodes on a fibre-optic based network with sub-nanosecond accuracy and picoseconds of jitter. This thesis evaluates WR as the TFT network for a coherent multistatic pulse-Doppler radar – NeXtRAD. To test the hypothesis that WR is suitable for TFT in a coherent multistatic radar, the time and frequency performance of a WR network was evaluated under laboratory conditions, comparing the results against a network of multi-channel GPS-disciplined oscillators (GPSDO). A WR-disciplined oscillator (WRDO) is introduced, which has the short-term stability of an ovenised crystal (OCXO), and long-term stability of the WR network. The radar references were measured using a dual mixer time difference technique (DMTD), which allows the phase to be measured with femtosecond level resolution. All references achieved the stringent time and frequency requirements for short-term coherent bistatic operation, however the GPSDOs and WRDOs had the best short-term frequency stability. The GPSDOs had the highest amount of long-term phase drift, with a peak-peak time error of 9.6 ns, whilst the WRDOs were typically stable to within 0.4 ns, but encountered transient phase excursions to 1.5 ns. The TFT networks were then used on the NeXtRAD radar, where a lighthouse, Roman Rock, was used as a static target to evaluate the time and frequency performance of the references on a real system. The results conform well to the laboratory measurements, and therefore, WR can be used for TFT in coherent radar

Power control for WCDMA

This project tries to introduce itself in the physical implementations that make possible the denominated third generation mobile technology. As well as to know the technology kind that makes possible, for example, a video-call in real time. During this project, the different phases passed from the election of WCDMA like the access method for UMTS will appear. Its coexistence with previous network GSM will be analyzed, where the compatibility between systems has been one of the most important aspects in the development of WCDMA, the involved standardization organisms in the process, as well as the different protocols that make the mobile communications within a network UTRAN possible. Special emphasis during the study of the great contribution that has offered WCDMA with respect to the control of power of the existing signals will be made. The future lines that are considered in the present, and other comment that already are in their last phase of development in the field of the mobile technology. UMTS through WCDMA can be summarized like a revolution of the air interface accompanied by a revolution in the network of their architecture