A Sub-Picosecond Hybrid DLL for Large-Scale Phased Array Synchronization

A large-scale timing synchronization scheme for scalable phased arrays is presented. This approach utilizes a DLL co-designed with a subsequent 2.5GHz PLL. The DLL employs a low noise, fine/coarse delay tuning to reduce the in-band rms jitter to 323fs, an order of magnitude improvement over previous works at similar frequencies. The DLL was fabricated in a 65nm bulk CMOS process and was characterized from 27MHz to 270MHz. It consumes up to 3.3mW from a 1V power supply and has a small footprint of 0.036mm^2

Digital Controlled Multi-phase Buck Converter with Accurate Voltage and Current Control

abstract: A 4-phase, quasi-current-mode hysteretic buck converter with digital frequency synchronization, online comparator offset-calibration and digital current sharing control is presented. The switching frequency of the hysteretic converter is digitally synchronized to the input clock reference with less than ±1.5% error in the switching frequency range of 3-9.5MHz. The online offset calibration cancels the input-referred offset of the hysteretic comparator and enables ±1.1% voltage regulation accuracy. Maximum current-sharing error of ±3.6% is achieved by a duty-cycle-calibrated delay line based PWM generator, without affecting the phase synchronization timing sequence. In light load conditions, individual converter phases can be disabled, and the final stage power converter output stage is segmented for high efficiency. The DC-DC converter achieves 93% peak efficiency for Vi = 2V and Vo = 1.6V.Dissertation/ThesisDoctoral Dissertation Electrical Engineering 201

High resolution FPGA DPWM based on variable clock phase shifting

Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works. A. de Castro, "High resolution FPGA DPWM based on variable clock phase shifting" IEEE Transactions on Power Electronics – Letters section, vol.25, no.5, pp.1115 - 1119, mayo 2010This paper proposes a very high resolution DPWM architecture that takes advantage of an FPGA advanced clock management capability: the fine phase shifting of the clock. This feature is available in almost every FPGA nowadays, allowing very small and programmable delays between the input and output clocks. An original use of this fine phaseshifting pushes the limits of DPWM resolution. The experimental results show a time resolution of 19.5 ps in a Virtex-5 FPGA

A Sub-Picosecond Hybrid DLL for Large-Scale Phased Array Synchronization

A large-scale timing synchronization scheme for scalable phased arrays is presented. This approach utilizes a DLL co-designed with a subsequent 2.5GHz PLL. The DLL employs a low noise, fine/coarse delay tuning to reduce the in-band rms jitter to 323fs, an order of magnitude improvement over previous works at similar frequencies. The DLL was fabricated in a 65nm bulk CMOS process and was characterized from 27MHz to 270MHz. It consumes up to 3.3mW from a 1V power supply and has a small footprint of 0.036mm^2

FULLY INTEGRATED HIGH-FREQUENCY CLOCK GENERATION AND SYNCHRONIZATION TECHINIQUES

Department of Electrical EngineeringThis thesis presents clock generation and synchronization techniques for RF wireless communication. First, it deals with voltage-controlled oscillators (VCOs) for local oscillators (LO) in transceivers, and secondly delay-locked loops for synchronization. For the high-performance LO, VCO is one of the key blocks. LC VCOs and ring VCOs are commonly-used types. Their characteristics are varied for different frequency bands. In this thesis, two types of VCOs, LC VCO and ring VCO, are presented with specific applications. For the multi-clock generator which could be used for carrier aggregation or frequency hopping, ring-type digitally controlled oscillator (DCO) was designed covering 900-1200 MHz with -165 dB FOM. For the multi-band frequency synthesizer which could be used for 5G communication with backward compatibility, three LC VCOs are designed which frequency range of 25-30 GHz for 5G, 5.2-6.0 GHz for LTE, 2.7-4.2 GHz for 2G-3G communication, respectively. For the clock synchronization in RF communications, a delay-locked loop (DLL) using a digital-to-analog converter (DAC) based band-selecting circuit (BSC) was presented to achieve a wide harmonic-locking-free frequency range. The BSC used the proposed exponential digital-to-analog converter (EDAC) to generate a collection of initial control voltages which follow a sequence of geometric with satisfying the condition for preventing harmonic locking problem. Therefore, the BSC can cover a much wider frequency range which is free from harmonic locking problem compared to initial band selection techniques using conventional, linear DAC (LDAC) that have a set of control voltages of arithmetic sequence. In this thesis, the DLL was implemented in a 65-nm CMOS process, and it had a measured frequency range from 100 to 1500 MHz which range is free from harmonic locking. The measure rms jitter and 1-MHz phase noise at 1000 MHz were 1.99 ps and ?28 dBc/Hz, respectively. The DLL consumes 5.5 mW and its active area was 0.052 mm2.clos

Time-to-digital converters and histogram builders in SPAD arrays for pulsed-LiDAR

Light Detection and Ranging (LiDAR) is a 3D imaging technique widely used in many applications such as augmented reality, automotive, machine vision, spacecraft navigation and landing. Pulsed-LiDAR is one of the most diffused LiDAR techniques which relies on the measurement of the round-trip travel time of an optical pulse back-scattered from a distant target. Besides the light source and the detector, Time-to-Digital Converters (TDCs) are fundamental components in pulsed-LiDAR systems, since they allow to measure the back-scattered photon arrival times and their performance directly impact on LiDAR system requirements (i.e., range, precision, and measurements rate). In this work, we present a review of recent TDC architectures suitable to be integrated in SPAD-based CMOS arrays and a review of data processing solutions to derive the TOF information. Furthermore, main TDC parameters and processing techniques are described and analyzed considering pulsed-LiDAR requirements

Investigations into design and control of power electronic systems for future microprocessor power supplies

Ph.DDOCTOR OF PHILOSOPH

데이터 전송로 확장성과 루프 선형성을 향상시킨 다중채널 수신기들에 관한 연구

학위논문 (박사)-- 서울대학교 대학원 : 전기·컴퓨터공학부, 2013. 2. 정덕균.Two types of serial data communication receivers that adopt a multichannel architecture for a high aggregate I/O bandwidth are presented. Two techniques for collaboration and sharing among channels are proposed to enhance the loop-linearity and channel-expandability of multichannel receivers, respectively. The first proposed receiver employs a collaborative timing scheme recovery which relies on the sharing of all outputs of phase detectors (PDs) among channels to extract common information about the timing and multilevel signaling architecture of PAM-4. The shared timing information is processed by a common global loop filter and is used to update the phase of the voltage-controlled oscillator with better rejection of per-channel noise. In addition to collaborative timing recovery, a simple linearization technique for binary PDs is proposed. The technique realizes a high-rate oversampling PD while the hardware cost is equivalent to that of a conventional 2x-oversampling clock and data recovery. The first receiver exploiting the collaborative timing recovery architecture is designed using 45-nm CMOS technology. A single data lane occupies a 0.195-mm2 area and consumes a relatively low 17.9 mW at 6 Gb/s at 1.0V. Therefore, the power efficiency is 2.98 mW/Gb/s. The simulated jitter is about 0.034 UI RMS given an input jitter value of 0.03 UI RMS, while the relatively constant loop bandwidth with the PD linearization technique is about 7.3-MHz regardless of the data-stream noise. Unlike the first receiver, the second proposed multichannel receiver was designed to reduce the hardware complexity of each lane. The receiver employs shared calibration logic among channels and yet achieves superior channel expandability with slim data lanes. A shared global calibration control, which is used in a forwarded clock receiver based on a multiphase delay-locked loop, accomplishes skew calibration, equalizer adaptation, and the phase lock of all channels during a calibration period, resulting in reduced hardware overhead and less area required by each data lane. The second forwarded clock receiver is designed in 90-nm CMOS technology. It achieves error-free eye openings of more than 0.5 UI across 9− 28 inch Nelco 4000-6 microstrips at 4− 7 Gb/s and more than 0.42 UI at data rates of up to 9 Gb/s. The data lane occupies only 0.152 mm2 and consumes 69.8 mW, while the rest of the receiver occupies 0.297 mm2 and consumes 56 mW at a data rate of 7 Gb/s and a supply voltage of 1.35 V.1. Introduction 1 1.1 Motivations 1.2 Thesis Organization 2. Previous Receivers for Serial-Data Communications 2.1 Classification of the Links 2.2 Clocking architecture of transceivers 2.3 Components of receiver 2.3.1 Channel loss 2.3.2 Equalizer 2.3.3 Clock and data recovery circuit 2.3.3.1. Basic architecture 2.3.3.2. Phase detector 2.3.3.2.1. Linear phase detector 2.3.3.2.2. Binary phase detector 2.3.3.3. Frequency detector 2.3.3.4. Charge pump 2.3.3.5. Voltage controlled oscillator and delay-line 2.3.4 Loop dynamics of PLL 2.3.5 Loop dynamics of DLL 3. The Proposed PLL-Based Receiver with Loop Linearization Technique 3.1 Introduction 3.2 Motivation 3.3 Overview of binary phase detection 3.4 The proposed BBPD linearization technique 3.4.1 Architecture of the proposed PLL-based receiver 3.4.2 Linearization technique of binary phase detection 3.4.3 Rotational pattern of sampling phase offset 3.5 PD gain analysis and optimization 3.6 Loop Dynamics of the 2nd-order CDR 3.7 Verification with the time-accurate behavioral simulation 3.8 Summary 4. The Proposed DLL-Based Receiver with Forwarded-Clock 4.1 Introduction 4.2 Motivation 4.3 Design consideration 4.4 Architecture of the proposed forwarded-clock receiver 4.5 Circuit description 4.5.1 Analog multi-phase DLL 4.5.2 Dual-input interpolating deley cells 4.5.3 Dedicated half-rate data samplers 4.5.4 Cherry-Hooper continuous-time linear equalizer 4.5.5 Equalizer adaptation and phase-lock scheme 4.6 Measurement results 5. Conclusion 6. BibliographyDocto