32 research outputs found

    Rigorous Stability Criterion for Digital Phase Locked Loops

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    This paper proposes a rigorous stability criterion for an arbitrary order digital phase locked loop (DPLL), with a charge pump phase frequency detector (CP-PFD) component. Stability boundaries for such systems are determined using piecewise linear methods to model the nonlinear nature of the CP-PFD component block. The model calculates the control voltage, after a predetermined number of input reference signal sampling periods, to a small initial voltage offset. This paper, in particular, takes an in-depth look at the second order system. The second order stability boundaries, as defined by the proposed technique, are compared to that of existing linear theory stability boundaries, and display a significant improvement. The applicability of the proposed technique to higher order systems, using a numerically iterative solution, is presented. Finally the proposed methodology is used to determine the stability boundary of a third order system and thus the component values for a stable system. Using these component values the response of the DPLL to an initial control voltage offset is simulated using a circuit level simulation. Index Terms—High Order, Phase Locked Loop, Piecewise Linear, Stability

    Rigorous Stability Criterion for Digital Phase Locked Loops

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    This paper proposes a rigorous stability criterion for an arbitrary order digital phase locked loop (DPLL), with a charge pump phase frequency detector (CP-PFD) component. Stability boundaries for such systems are determined using piecewise linear methods to model the nonlinear nature of the CP-PFD component block. The model calculates the control voltage, after a predetermined number of input reference signal sampling periods, to a small initial voltage offset. This paper, in particular, takes an in-depth look at the second order system. The second order stability boundaries, as defined by the proposed technique, are compared to that of existing linear theory stability boundaries, and display a significant improvement. The applicability of the proposed technique to higher order systems, using a numerically iterative solution, is presented. Finally the proposed methodology is used to determine the stability boundary of a third order system and thus the component values for a stable system. Using these component values the response of the DPLL to an initial control voltage offset is simulated using a circuit level simulation. Index Terms—High Order, Phase Locked Loop, Piecewise Linear, Stability

    System level performance and yield optimisation for analogue integrated circuits

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    Advances in silicon technology over the last decade have led to increased integration of analogue and digital functional blocks onto the same single chip. In such a mixed signal environment, the analogue circuits must use the same process technology as their digital neighbours. With reducing transistor sizes, the impact of process variations on analogue design has become prominent and can lead to circuit performance falling below specification and hence reducing the yield.This thesis explores the methodology and algorithms for an analogue integrated circuit automation tool that optimizes performance and yield. The trade-offs between performance and yield are analysed using a combination of an evolutionary algorithm and Monte Carlo simulation. Through the integration of yield parameter into the optimisation process, the trade off between the performance functions can be better treated that able to produce a higher yield. The results obtained from the performance and variation exploration are modelled behaviourally using a Verilog-A language. The model has been verified with transistor level simulation and a silicon prototype.For a large analogue system, the circuit is commonly broken down into its constituent sub-blocks, a process known as hierarchical design. The use of hierarchical-based design and optimisation simplifies the design task and accelerates the design flow by encouraging design reuse.A new approach for system level yield optimisation using a hierarchical-based design is proposed and developed. The approach combines Multi-Objective Bottom Up (MUBU) modelling technique to model the circuit performance and variation and Top Down Constraint Design (TDCD) technique for the complete system level design. The proposed method has been used to design a 7th order low pass filter and a charge pump phase locked loop system. The results have been verified with transistor level simulations and suggest that an accurate system level performance and yield prediction can be achieved with the proposed methodology

    데이터 전송로 확장성과 루프 선형성을 향상시킨 다중채널 수신기들에 관한 연구

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    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

    Design and realization of a 2.4 Gbps - 3.2 Gbps clock and data recovery circuit

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    This thesis presents the design, verification, system integration and the physical realization of a high-speed monolithic phase-locked loop (PLL) based clock and data recovery (CDR) circuit. The architecture of the CDR has been realized as a two-loop structure consisting of coarse and fine loops, each of which is capable of processing the incoming low-speed reference clock and high-speed random data. At start up, the coarse loop provides fast locking to the system frequency with the help of the reference clock. After the VCO clock reaches a proximity of system frequency , the LOCK signal is generated and the coarse loop is tumed off, while the fine loop is tumed on. Fine loop tracks the phase of the generated clock with respect to the data and aligns the VCO clock such that its rising edge is in the middle of data eye. The speed and symmetry of sub-blocks in fine loop are extremely important, since all asymmetric charging effects, skew and setup/hold problems in this loop translate into a static phase error at the clock output. The entire circuit architecture is built with a special low-voltage circuit design technique. All analogue as well as digital sub-blocks of the CDR architecture presented in this work operate on a differential signalling, which significantly makes the design more complex while ensuring a more robust perforrnance. Other important features of this CDR include small area, single power supply, low power consumption, capability to operate at very high data rates, and the ability to handle between 2.4 Gbps and 3.2 Gbps data rate. The CDR architecture was realized using a conventional 0.13-mikrometer digital CMOS technology (Foundry: UMC), which ensures a lower overall cost and better portability for the design. The CDR architecture presented in this work is capable of operating at sampling frequencies of up to 3.2 GHz, and still can achieve the robust phase alignrnent. The entire circuit is designed with single 1.2 V power supply .The overall power consumption is estimated as 18.6 mW at 3.2 GHz sampling rate. The overall silicon area of the CDR is approximately 0.3 mm^2 with its internal loop filter capacitors. Other researchers have reported similar featured PLL-based clock and data recovery circuits in terms of operating data rate, architecture and jitter performance. To the best of our knowledge, this clock recovery uses the advantage of being the first high-speed CDR designed in CMOS 0.13 mikrometer technology with the superiority on power consumption and area considerations among others. The CDR architecture presented in this thesis is intended, as a state-of-the-art clock recovery for high-speed applications such as optical communications or high bandwidth serial wireline communication needs. It can be used either as a stand-alone single-chip unit, or as an embedded intellectual property (IP) block that can be integrated with other modules on chip

    Design and modelling of clock and data recovery integrated circuit in 130 nm CMOS technology for 10 Gb/s serial data communications

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    This thesis describes the design and implementation of a fully monolithic 10 Gb/s phase and frequency-locked loop based clock and data recovery (PFLL-CDR) integrated circuit, as well as the Verilog-A modeling of an asynchronous serial link based chip to chip communication system incorporating the proposed concept. The proposed design was implemented and fabricated using the 130 nm CMOS technology offered by UMC (United Microelectronics Corporation). Different PLL-based CDR circuits topologies were investigated in terms of architecture and speed. Based on the investigation, we proposed a new concept of quarter-rate (i.e. the clocking speed in the circuit is 2.5 GHz for 10 Gb/s data rate) and dual-loop topology which consists of phase-locked and frequency-locked loop. The frequency-locked loop (FLL) operates independently from the phase-locked loop (PLL), and has a highly-desired feature that once the proper frequency has been acquired, the FLL is automatically disabled and the PLL will take over to adjust the clock edges approximately in the middle of the incoming data bits for proper sampling. Another important feature of the proposed quarter-rate concept is the inherent 1-to-4 demultiplexing of the input serial data stream. A new quarter-rate phase detector based on the non-linear early-late phase detector concept has been used to achieve the multi-Giga bit/s speed and to eliminate the need of the front-end data pre-processing (edge detecting) units usually associated with the conventional CDR circuits. An eight-stage differential ring oscillator running at 2.5 GHz frequency center was used for the voltage-controlled oscillator (VCO) to generate low-jitter multi-phase clock signals. The transistor level simulation results demonstrated excellent performances in term of locking speed and power consumption. In order to verify the accuracy of the proposed quarter-rate concept, a clockless asynchronous serial link incorporating the proposed concept and communicating two chips at 10 Gb/s has been modelled at gate level using the Verilog-A language and time-domain simulated

    Event-Driven Simulation Methodology for Analog/Mixed-Signal Systems

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    학위논문 (박사)-- 서울대학교 대학원 : 전기·컴퓨터공학부, 2015. 8. 김재하.Recent system-on-chip's (SoCs) are composed of tightly coupled analog and digital components. The resulting mixed-signal systems call for efficient system-level behavioral simulators for fast and systematic verifications. As the system-level verifications rely heavily on digital verification tools, it is desirable to build the mixed-signal simulator based on a digital simulator. However, the existing solutions in digital simulators suffer from a trade-off between simulation speed and accuracy. This work breaks down the trade-off and realizes a fast and accurate analog/mixed-signal behavior simulation in a digital simulator SystemVerilog. The main difference of the proposed methodology from existing ones is its way of representing continuous-time signals. Specifically, a clock signal expresses accurate timing information by carrying an additional real-value time offset, and an analog signal represents its continuous-time waveform in a functional form by employing a set of coefficients. With these signal representations, the proposed method accurately simulates mixed-signal behaviors independently of a simulator's time-step and achieves a purely event-driven simulation without involving any numerical iteration. The speed and accuracy of the proposed methodology are examined for various types of analog/mixed-signal systems. First, timing-sensitive circuits (a phase-locked loops and a clock and data recovery loop) and linear analog circuits (a channel and linear equalizers) are simulated in a high-speed I/O interface example. Second, a switched-linear-behavior simulation is demonstrated through switching power supplies, such as a boost converter and a switched-capacitor converter. Additionally, the proposed method is applied to weakly nonlinear behaviors modeled with a Volterra series for an RF power amplifier and a high-speed I/O linear equalizer. Furthermore, the nonlinear behavior simulation is extended to three different types of injection-locked oscillators exhibiting time-varying nonlinear behaviors. The experimental results show that the proposed simulation methodology achieved tens to hundreds of speed-ups while maintaining the same accuracy as commercial analog simulators.ABSTRACT I CONTENTS III LIST OF FIGURES V LIST OF TABLES XII CHAPTER 1 INTRODUCTION 1 1.1 BACKGROUND 1 1.2 MAIN CONTRIBUTION 6 1.3 THESIS ORGANIZATION 8 CHAPTER 2 EVENT-DRIVEN SIMULATION OF ANALOG/MIXED-SIGNAL BEHAVIORS 9 2.1 PROPOSED CLOCK AND ANALOG SIGNAL REPRESENTATIONS 10 2.2 SIGNAL TYPE DEFINITIONS IN SYSTEMVERILOG 14 2.3 EVENT-DRIVEN SIMULATION METHODOLOGY 16 CHAPTER 3 HIGH-SPEED I/O INTERFACE SIMULATION 21 3.1 CHARGE-PUMP PHASE-LOCKED LOOP 23 3.2 BANGBANG CLOCK AND DATA RECOVERY 37 3.3 CHANNEL AND EQUALIZERS 45 3.4 HIGH-SPEED I/O SYSTEM SIMULATION 52 CHAPTER 4 SWITCHING POWER SUPPLY SIMULATION 55 4.1 BOOST CONVERTER 57 4.2 TIME-INTERLEAVED SWITCHED-CAPACITOR CONVERTER 66 CHAPTER 5 VOLTERRA SERIES MODEL SIMULATION 72 5.1 VOLTERRA SERIES MODEL 74 5.2 CLASS-A POWER AMPLIFIER 79 5.3 CONTINUOUS-TIME EQUALIZER 84 CHAPTER 6 INJECTION-LOCKED OSCILLATOR SIMULATION 89 6.1 PPV-BASED ILO MODEL 91 6.2 LC OSCILLATOR 99 6.3 RING OSCILLATOR 104 6.4 BURST-MODE CLOCK AND DATA RECOVERY 109 CONCLUSION 116 BIBLIOGRAPHY 118 초 록 126Docto

    Impact of the pulvinar on the ventral pathway of the cat visual cortex

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    Signals from the retina are relayed to the lateral geniculate nucleus from which they are sent to the primary visual cortex. At the cortical level, the information is transferred across several visual areas in which the complexity of the processing increases progressively. Anatomical and functional evidence demonstrate the existence of two main pathways in visual cortex processing distinct features of the visual information: the dorsal and ventral streams. Cortical areas composing the dorsal stream are implicated mostly in motion processing while those comprising the ventral stream are involved in the processing of form and colour. This classic view of the cortical functional organization is challenged by the existence of reciprocal connections of visual cortical areas with the thalamic nucleus named pulvinar. These connections allow the creation of a trans-thalamic pathway that parallels the cortico-cortical communications across the visual hierarchy. The main goal of the present thesis is twofold: first, to obtain a better comprehension of the processing of light increments and decrements in an area of the cat ventral stream (area 21a); second, to characterize the nature of the thalamo-cortical inputs from the cat lateral posterior nucleus (LP) to area 21a. In study #1, we investigated the spatiotemporal response profile of neurons from area 21a to light increments (brights) and decrements (darks) using a reverse correlation analysis of a sparse noise stimulus. Our findings showed that 21a neurons exhibited stronger responses to darks with receptive fields exhibiting larger dark subfields. However, no differences were found between the temporal dynamics of brights and darks. In comparison with the primary visual cortex, the dark preference in area 21a was found to be strongly enhanced, supporting the notion that the asymmetries between brights and darks are transmitted and amplified along the ventral stream. In study #2, we investigated the impact of the reversible pharmacological inactivation of the LP nucleus on the contrast response function (CRF) of neurons from area 21a and the primary visual cortex (area 17). The thalamic inactivation yielded distinct effects on both cortical areas. While in area 17 the LP inactivation caused a slight decrease in the response gain, in area 21a a strong increase was observed. Thus, our findings suggest that the LP exerts a modulatory influence on the cortical processing along the ventral stream with stronger impact on higher order extrastriate areas. Taken together, our findings allowed a better comprehension of the functional properties of the cat ventral stream and contributed to the current knowledge on the role of the pulvinar on the cortico-thalamo-cortical processing of visual information.Les signaux provenant de la rétine sont relayés dans le corps géniculé latéral où ils sont envoyés au cortex visuel primaire. L’information passe ensuite à travers plusieurs aires visuelles où la complexité du traitement augmente progressivement. Des données tant anatomiques que fonctionnelles ont démontré l’existence de deux voies principales qui traitent différentes propriétés de l’information visuelle : les voies dorsale et ventrale. Les aires corticales composant la voie dorsale sont impliquées principalement dans le traitement du mouvement tandis que les aires de la voie ventrale sont impliquées dans le traitement de la forme et de la couleur. Cette vision classique de l’organisation fonctionnelle du cortex est toutefois remise en question par l’existence de connections réciproques entre les aires corticales visuelles et le pulvinar, un noyau thalamique. En effet, ces connections permettent la création d’une voie trans-thalamique parallèle aux connections cortico-corticales à travers la hiérarchie visuelle. Le but principal de la présente thèse consiste en deux volets : le premier est d’obtenir une meilleure compréhension du traitement des incréments et décréments de la lumière dans une aire de la voie ventrale du chat (aire 21a); le second est de caractériser la nature des inputs thalamo-corticaux du noyau latéral postérieur (LP) à l’aire 21a chez le chat. Dans l’étude #1, nous avons investigué le profil spatiotemporel des réponses des neurones de l’aire 21a aux incréments (blancs) et décréments (noirs) de lumière en utilisant l’analyse de corrélation inverse d’un stimulus de bruit épars. Les neurones de l’aire 21a ont répondu plus fortement aux stimuli noirs, en montrant des champs récepteurs avec des sous-champs noirs plus larges. Cependant, aucune différence n’a été trouvée en ce qui concerne les dynamiques temporelles des réponses aux blancs et aux noirs. En comparaison avec le cortex visuel primaire, la préférence aux stimuli noirs dans l’aire 21a s’est avérée fortement augmentée. Ces données indiquent que les asymétries entre les réponses aux blancs et aux noirs sont transmises et amplifiées à travers la voie ventrale. Dans l’étude #2, nous avons investigué l’impact de l’inactivation pharmacologique réversible du noyau LP sur la fonction de réponse au contraste (CRF) des neurones de l’aire 21a et du cortex visuel primaire (aire 17). L’inactivation a eu différents effets dans les deux aires corticales. Alors que, dans l’aire 17, l’inactivation du LP a causé une légère réduction du gain de la réponse, une forte augmentation a été observée dans l’aire 21a. Ainsi, nos résultats suggèrent que le LP exerce une influence modulatrice dans le traitement cortical à travers la voie ventrale avec un impact plus important dans des aires extrastriées de plus haut niveau. Nos résultats ont permis d’avoir une meilleure compréhension des propriétés fonctionnelles de la voie ventrale du chat et de contribuer à enrichir les connaissances actuelles sur le rôle du pulvinar dans le traitement cortico-thalamo-cortical de l’information visuelle
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