A LOW POWER TIME-TO-DIGITAL CONVERTER FOR ALL-DIGITAL PHASE-LOCKED LOOP

Time-to-Digital Converter (TDC) is a key block used as the phase/frequency detector in an All-Digital Phase-Locked Loop (ADPLL). Usually, it occupies a large proportion of ADPLL's total power consumption up to about 30% to 40%. In this paper, the detailed power consumption of different components in the TDC is analyzed. A Power Management Block (PMB) is presented for the TDC to reduce its power consumption. A 24-bits TDC core with the proposed PMB is implemented in HJTC 0.18 μm CMOS technology. Simulation results show that up to 84% power reduction is achieved using our proposed technique.

A Digital Phase Locked Loop Speed Control of Three Phase Induction Motor Drive: Performances Analysis

This paper deals with performance analysis and implementation of a three phase inverter fed induction motor (IM) drive system. The closed loop control scheme of the drive utilizes the Digital Phase Locked Loop (DPLL). The DPLL is safely implemented all around the well known integrated circuit DPLL 4046. An ex-perimental verification is carried out on one kw scalar controlled IM system drives for a wide range of speeds and loads appliance. This presents a simple and high performance solution for industrial applications.

THE DESIGN OF AN ALL-DIGITAL PHASE-LOCKED LOOP WITH LOW JITTER BASED ON ISF ANALYSIS

A low jitter All-Digital Phase-Locked Loop （ADPLL） used as a clock generator is designed. The Digital-Controlled Oscillator （DCO） for this ADPLL is a seven-stage ring oscillator with the delay of each stage changeable. Based on the Impulse Sensitivity Function （ISF） analysis, an effective way is proposed to reduce the ADPLL＇s jitter by the careful design of the sizes of the inverters used in the DCO with a simple architecture other than a complex one. The ADPLL is implemented in a 0.18μm CMOS process with 1.SV supply voltage, occupies 0.046mm^2 of on-chip area. According to the measured results, the ADPLL can operate from 108MHz to 304MHz, and the peak-to-peak jitter is 139ps when the DCO＇s output frequency is 188MHz.

Dynamic Free-Spectral-Range Measurement for Fiber Resonator Based on Digital-Heterodyne Optical Phase-Locked Loop

We propose a novel scheme, based on digital-heterodyne optical phase-locked loop with whole-fiber circuit, to dynamically measure the free-spectral-range of a fiber resonator. The optical phase-locked loop is established with a differential frequency-modulation module consists of a pair of acousto-optic modulators. The resonance-tracking loop is derived with the Pound-Drever-Hall technique for locking the heterodyne frequency of the OPLL on the frequency difference between adjacent resonance modes. A stable locking accuracy of about 7 × 10?9 and a dynamic locking accuracy of about 5 × 10?8 are achieved with the FSR of 8.155 MHz, indicating a bias stability of the resonator fiber optic gyro of about 0.1?/h with 10 Hz bandwidth. In addition, the thermal drift coefficient of the FSR is measured as 0.1 Hz/?C. This shows remarkable potential for realizing advanced optical measurement systems, such as the resonant fiber optic gyro, and so on.

基于DPLL的扫频信号源系统的设计与实现

扫频信号源是输出频率可数控步进调整的正弦波信号源。低相位噪声和杂散的高频谱纯度扫频信号源是组成雷达接收机和系统频域分析设备等的核心。文中以数字锁相环技术(DPLL)作为高频谱纯度信号输出核心,用分频寄存器的设置来控制信号的输出频率,并通过高阶滤波器和自动增益系统得到最终的扫频信号输出频率。电路中,基于ADF4002数字鉴频鉴相器芯片、MC12148压控振荡器芯片和无源滤波器电路构建数字锁相环,再通过VCA821实现自动增益控制电路,最终实现高频谱纯度扫频信号源。经测试,该扫频信号源能在40~120 MHz范围实现较高频谱纯度的扫频信号输出,将DPLL技术应用于扫频信号源不但易于变频和加快扫频源的迭代,而且大幅度降低了硬件开发成本。

Linearized Phase Detector Zero Crossing DPLL Performance Evaluation in Faded Mobile Channels

Zero Crossing Digital Phase Locked Loop with Arc Sine block (AS-ZCDPLL) is used to linearize the phase difference detection, and enhance the loop performance. The loop has faster acquisition, less steady state phase error, and wider locking range compared to the conventional ZCDPLL. This work presents a Zero Crossing Digital Phase Locked Loop with Arc Sine block (ZCDPLL-AS). The performance of the loop is analyzed under mobile faded channel conditions. The mobile channel is assumed to be two path fading channel corrupted by additive white Gaussian noise (AWGM). It is shown that for a constant filter gain, the frequency spread has no effect on the steady state phase error variance when the loop is subjected to a phase step. For a frequency step and under the same conditions, the effect on phase error is minimal.

Research into the sampling methods of digital beam position measurement

A fully digital beam position monitoring system(DBPM) has been designed for SSRF(Shanghai Synchrotron Radiation Facility). As analog-to-digital converter(ADC) is a crucial part in the DBPM system, the sampling methods should be studied to achieve optimum performance. Different sampling modes were used and compared through tests. Long term variation among four sampling channels, which would introduce errors in beam position measurement, is investigated. An interleaved distribution scheme was designed to address this issue. To evaluate the sampling methods, in-beam tests were conducted in SSRF. Test results indicate that with proper sampling methods, a turn-by-turn(TBT) position resolution better than 1 μm is achieved, and the slow-acquisition(SA) position resolution is improved from 4.28 μm to 0.17 μm.

基于电容电压全前馈的并网逆变器高鲁棒性稳定控制策略

虽然并网逆变器采用电容电压全前馈控制策略,能够有效抑制电网电压背景谐波对并网电流的影响。但是在弱电网工况环境下,由于锁相环、数字控制延时等因素与电网阻抗相互耦合,导致逆变器稳定较差、在阻抗交截频域中呈现弱无源性,易引发系统谐波振荡甚至失稳问题。鉴于此,该文借助无源性理论和阻抗分析方法,深度揭示了影响系统各频带阻抗特性的主导因素,进而提出了一种基于电容电压全前馈的并网逆变器高鲁棒性稳定控制策略。理论分析表明:所提控制策略不仅能有效地拓宽系统输出阻抗稳定范围,还可以保证改进后的系统输出阻抗具有较高的幅值增益。最后,通过仿真和实验验证了所提控制策略的有效性。

带残余频偏的软扩频信号伪码序列盲估计

针对带残余频偏的软扩频信号伪码序列盲估计难的问题,提出一种奇异值分解(singular value decomposition,SVD)结合全数字锁相环(digital phase locked loop,DPLL)的方法。所提方法首先对待处理信号通过不重叠分段生成数据矩阵,每段信号长度为一倍伪码周期;然后利用其自相关矩阵的右上角元素估计失步点进行同步,并且在重新计算自相关矩阵后根据较大特征值个数估计进制数;最后通过多次快速SVD算法结合DPLL最终实现伪码序列的盲估计。仿真结果显示,所提方法在低信噪比条件下可以有效估计出带残余频偏的软扩频信号的伪码序列,并且性能优于其他对比方法。

一种适用于亚采样锁相环的高鲁棒性辅助锁定电路

当前的研究表明,基于亚采样相位检测器(Sub-Sampling Phase Detectors,SSPD)的锁相环(Phase-Locked Loop,PLL)相较传统锁相环架构可以实现显著降低的带内相位噪声。然而,在片上系统(Systems on Chip,SOCs)应用中,PLL容易受到衬底或电源耦合的干扰,这很可能会导致PLL失去锁定,且可能无法恢复。针对此问题,提出一种将辅助锁频环(Frequency-Locked Loop,FLL)和数字锁定检测器(Digital Lock Detector,DLD)相结合的适用于亚采样锁相环(Sub-Sampling Phase-Locked Loop,SSPLL)的高鲁棒性辅助锁定电路。仿真结果表明:与传统SSPLL相比,所提出的电路极大提升了PLL对衬底或电源干扰的鲁棒性,同时保持了其低相位噪声的优点,这对于SSPLL在大规模生产和应用中的可靠性具有重要意义。

面向悬浮光力系统的集成化反馈控制器研究

悬浮光力系统具有高灵敏度、高稳定性和低耗散等特点,有望发展成为新型高性能力学传感器。针对目前悬浮光力系统存在的反馈控制器兼容性差、软硬件成本高、集成度低等问题,提出了一种兼容多种反馈控制模式的软硬件设计方案,并研制了一套高度集成的反馈控制器,在160 mm×170 mm×42 mm的尺寸上集成了六通道模数/数模转换器、滤波器、现场可编程门阵列+微处理器(FPGA+ARM)等功能模块,并且开发了基于数字锁相环和比例积分微分(PID)控制器的控制算法,最终在同一套硬件系统上实现了跨尺度微粒的运动信息采集和反馈控制,以及数十赫兹至亚兆赫兹的感知带宽。实验结果表明,该集成反馈控制器能够实现超高真空(10-6 Pa量级)下亚微米及微米尺度微粒的稳定悬浮和运动控制。在扩展系统感知带宽的同时减小了整体体积,为悬浮光力传感技术的器件化奠定了基础。

Fuzzy-DPLL在感应加热电源中的应用与研究

提出了在感应加热电源中采用模糊控制与数字锁相环相结合的负载频率跟踪方法,介绍了模糊控制与数字锁相环(Fuzzy-DPLL)控制器的原理及设计,并在Matlab中进行系统建模及验证,仿真及实验结果表明,采用Fuzzy-DPLL复合控制的感应加热设备具有快速的动态性能和高精度的稳态性能。

包含过渡区的可自动变模数字锁相环

针对传统的数字锁相环频带窄,速度慢,只能锁定中心频率附近频率的缺点,提出了一种具有快捕区、中捕区、过渡区和慢捕区的可变模可监测频率改变的全数字锁相环。该数字锁相环具有自动变模功能,可在锁定过程中自动改变数字滤波器模的值。针对传统数字锁相环在锁定快结束阶段容易进入慢捕区的缺点,在原有的捕捉区域中增加了过渡区,进一步加快了锁定速度。当输入的参考信号频率较高时,环路锁定速度更快。当参考信号在41.67~500 kHz时,系统最快可以在7.64μs内完成锁定。在锁定过程的后阶段,参考信号与输出信号的相位差个数在1~5个系统时钟中均匀分布,相位差系统时钟个数为5、3、2时的锁定速度快于相位差系统时钟个数为4、1。

基于VerilogHDL语言的DPLL的数控振荡器设计

随着通讯技术、集成电路技术的飞速发展和系统芯片(SoC)的深入研究,数字锁相环技术应用越来越广泛。数字锁相环数控振荡器设计是数字锁相环电路的关键部分,在利用Verilog语言配合Xilinx的FPGA的基础上,采用两种方法实现数控振荡电路。一种是根据脉冲加/减电路编写RTL代码实现;另一种是采用有限状态机编写RTL代码实现。并使用综合软件Synplify7.5对两种满足设计要求的RTL代码进行综合分析。

一种改进型DPLL在VIENNA整流器中的应用研究

在分析VIENNA整流器电压同步控制策略的基础上,针对三相输入电压不平衡情况下相位难以锁定及定点DSP难以实现三角函数运算的问题,探讨了一种将陷波滤波器串入三相数字锁相环(DPLL)和使用数字正弦振荡器的改进型DPLL方法。以TMS320F2808作为控制核心,构建了一台3 kW VIENNA整流器实验样机,实验结果表明该改进型DPLL计算时间短、锁相准确,VIENNA整流器可实现高功率因数校正。

基于DDS/DPLL的宽带雷达信号设计

本文提出一种用DDS激励DPLL产生宽带雷达信号波形方案设计,该方案具有控制简单、编程灵活、可靠性高等特点,并在SystemView平台下实现了电路仿真,对仿真结果进行了分析。从仿真结果看出系统的设计,具有工作频率高、频率的分辨率高、频带宽及频谱纯等特点。能够很好地满足工程上应用,实现产生宽带雷达信号波形的需要。

激光陀螺机抖控制的DDS锁相频率合成方法及其国产化设计

激光陀螺通常采用数模转换器(DAC)配合模拟乘法器产生正弦自激振荡的机抖控制方式,乘法器模块现阶段没有国产化替代方案,存在自激振荡在高低温条件下偶发不起振问题。因此,选用国产化微处理器MCU配合DAC替换乘法器模块,采用捕获抖动过零信号快速获得控制相位,使用PI控制器进行相位-频率差运算,采取查找表方式实现频率合成,输出周期驱动信号(正弦信号或三角波信号),实现抖动偏频闭环控制。所提方案在某三轴一体小型化三自惯组产品50型陀螺控制系统中应用,实现了关键器件的国产化替代设计,且陀螺系统固定位置百秒计数均值的标准方差优于5‰。

基于先进CMOS工艺的多通道Gbps LVDS接收器

在SIP(System In a Package)系统中集成具有LVDS(Low-Voltage Differential Signal)接口的多通道高速模数转换器(Analog-to-Digital Converter,ADC)时,面临不同LVDS输出通道延时不同所导致的数据采集错误的问题,为此设计了一个多通道自适应LVDS接收器。通过采用数据时钟恢复技术产生一个多相位的采样时钟,并结合ADC的测试模式来确认每一个通道的采样相位,能够自动对每一个通道的延时分别进行调整,以达到对齐各通道采样相位点,保证数据正确采集的目的。最后,基于先进CMOS工艺进行了接收器的设计、仿真、后端设计实现和流片测试,仿真和流片后的板级测试结果均表明该接收器能够对通道延迟进行自动调节以对齐采样相位,且最大的采样相位调节范围为±3 bit,信噪比大于65 dB,满足了设计要求和应用需求。

应用于汽车FMCW雷达的超前进位锁相环研究

近年来汽车FMCW雷达广泛应用于新能源及智能网联领域,来测量外部目标的相对间距和速度。针对当前FMCW雷达系统灵敏度差、缺少灵活性、测量范围窄的问题,设计了一种应用于FMCW雷达领域的超前进位全数字锁相环。根据雷达对物体距离和速度的测量原理,采取集成电路芯片技术实现了对该环路结构的设计,利用Matlab软件搭建环路系统Z域模型并进行了稳定性分析对比,通过硬件描述语言(VHDL)编写环路程序,并联合调用Modelsim软件完成了仿真试验,最后结合仿真结果在硬件上验证设计的准确性。实验结果表明,基于超前进位的全数字锁相环有效提高了锁相频率,降低了系统延时,大幅度拓展了调频范围。

大气激光通信中时隙同步器的DPLL设计

介绍了时隙同步器的结构,分析了数字锁相环（DPLL）的组成,说明了数字锁相环的工作过程。最后,提出一种VHDL设计的数字锁相环方案。