抖动和眼图的视觉分析

抖动和眼图的视觉化分析抖动为实际数据与其理想位置的时间偏差TIE 为信号相对于标准时钟或者标准信号的定时误差TIE 在高速数字系统中即为抖动…0.0ns0.990ns 2.000ns 2.980ns 4.000nsP2P3P4P1TIE0.000ns-0.010ns0.000ns-0.020ns眼图是怎么形成的？Random Jitter(随机抖动)•随机抖动符合高斯型分布•直方图(估计) ↔ pdf(数学模型)•抖动峰峰值=无穷大…无界！1-sigma or RMS 7-sigma•内部热能现象•Flicker Noise, Shot Noise •热能的原子与分子振动•分子的解体•外部的宇宙射线Deterministic Jitter(确定性抖动)•确定性抖动是非高斯分布并且有界Peak-to-PeakPeriodic Jitter(周期性抖动)•TIE 随时间的变化是重复的、周期性的•Periodic jitter 和相位调制(PM)是等效的Peak-to-Peak•系统时钟（抖动频率在MHz 量级）•开关电源（抖动频率在KHz 量级）Duty Cycle distortion(占空比失真)•上升时间和下降时间不对称•或者测试时参考电平选择不当0.0v-0.1vInter-Symbol Interference(码间干扰抖动)•DDJ 或PDJ –数据相关性抖动或码型相关性抖动,和ISI的术语是等价的.•码型是如何影响随后的比特位的？◦由于传输链路的效应、反射等换个角度看抖动，时域看看我们有了什么视角？抖动视觉化–时间趋势图▪直方图告诉了我们分布，但是只有统计特性，缺少了时间信息▪时间趋势图可以直观告诉我们波形里是否有特定频率的调制▪下图为5个周期SSC @ 30khz抖动视觉化Gaussian Random Noise Sinusoidal Jitter抖动视觉化–频谱图▪从频域上观测抖动▪抖动中决定性的频率成分会在谱线上明显超出噪底哪个眼图好？哪个直方图好？视觉化眼图和抖动的问题？浴盆曲线误码率是关键vs. UI 张开程度•For a given position in the time there’s a given probability of error –“BER ”, Bit Error Ratio•For a given position in the time there’s a given probability of signal crossing –PDF , probability density function1 UIP r o b a b i l i t y o f ‘h i t ’P r o b a b i l i t y o f E r r o r –B E R基于示波器分析的浴盆曲线Rj δδ/Dj δδ与Tj @ BERAssume bi-modal distribution (dual-Dirac), measure Tj at two BER Fit curve to points, slope is Rj, Intercept is DjMeasuredTj @ 10-7MeasuredTj @ 10-4½Dj δδ½xRj δδEstimatedTj @ 10-12x≈7.4σx≈10.4σx≈14.1σ双狄拉克模型Conditions: only where Gaussian.抖动类型分析•抖动分离为误码产生的根本原因提供了更精确的定位和分析方法•抖动分析方法，参照T11 MJSQ ，已经被工业界广泛接受Constituent Components of Jitter= Unbounded= Bounded Total Jitter(TJ)Duty-Cycle Jitter (DCD)Data Dependent Jitter (DDJ)Periodic Jitter(PJ)Deterministic Jitter (DJ)Random Jitter(RJ)Jitter Visualization –Bathtub Plot▪Shows the Eye Opening at a Specified BER Level▪Note the eye closure of System I vs. System II due to the RJ-RJ is unbounded so the closure increases as BER level increases▪System I has .053UI of RJ with no PJ▪System II has .018UI of RJ and .14UI of PJ @ 5 and 10MhzSystem I System ISystem II System IITektronix -Innovators of Jitter Analysis •1998First Real-Time Scope Based Jitter Analysis Software•2002 Invented SW Based PLL Clock Recovery and the Spectral Approach for Jitter Separation•2004–Invented RT Eye rendering on a Real Time Scope•2004-First vendor to support both modeled (Dual-Dirac) and measured (Spectral) jitter methods •2005-Invented measurements with Jitter and Noise reconciliation•2011-First scope vendor with BUJ support•2015–RT Noise Analysis and Sampling BER and PDF Mask Testing抖动和眼图的视觉化眼图怎么切割的？时钟决定！TIE 抖动需要参考时钟•参考时钟提取的过程就是时钟恢复•参考时钟有几种确定的方式:◦Constant Clock with Minimum Mean Squared ErrorThis is the mathematically “ideal” clockBut, only applicable when post-processing a finite-length waveformBest for showing very-low-frequency effectsAlso shows very-low-frequency effects of scope’s timebase◦Phase Locked Loop (e.g. Golden PLL)Tracks low-frequency jitter (e.g. clock drift)Models “real world” clock recovery circuits very well◦Explicit ClockThe clock is not recovered, but is directly probed◦Explicit Clock (Subrate)The clock is directly probed, but must be multiplied up by some integral factorImportance of Clock Recovery•From spec, “The jitter measurement device shall comply with the JTF”.•How do I verify JTF?◦JTF is difference between input clock (ref) and input clock(unfiltered)◦Use 1100b or 0011b pattern (proper 50% transition density)◦Check 1) LF attenuation, 2) -3 dB corner frequency, and 3) slope23JTF vs PLL Loop Bandwidth•Configuring the correct PLL settings is key to correctmeasurements•Most standards have a reference/defined CR setup◦For example, USB 3.0 uses a Type II with JTF of 4.9Mhz•Type I PLL◦Type I PLL has 20dB of roll off per decade◦JTF and PLL Loop Bandwidth are Equal•Type 2 PLL◦Type II PLL has 40dB of roll off per decade◦JTF and PLL Loop Bandwidth are not Equal▪For example, USB 3.0 uses a Type 2 PLL with a JTF of 4.9Mhz.The corresponding loop bandwidth is 10.126 Mhz▪Setting the Loop Bandwidth as opposed to JTF will lead to24PLL Loop Bandwidth vs. Jitter Transfer Function(JTF)JTF Filtering Effects based on different PLL bandwidthsf3dB= 30 kHz f3dB= 300 kHz f3dB= 3 MHzJitter for Busy People Hints, Tips and Common ErrorsUsing the Jitter Analysis Tools•Issues manifested in different layers of theprotocol stack◦Crosstalk, jitter, reflections, skew◦Disparity, encoding or CRC errors•Where do I start debugging?•Jitter and Eye Diagram Tools◦Oscilloscope-based for quick results▪Fast jitter measurements with▫‘One Button’ Jitter Wizard▪Compare timing, jitter, eye, amplitude measurements▪User-definable clock recovery, filters, pass/fail limits, andreference levelsMore Hints for Successful Jitter Analysis•Clock Recovery has a great deal of influence on jitter results. Think about what you’re trying to accomplish.◦Constant-Clock is the most “unbiased”Often best if you’re trying to see very-low-frequency effectsBut it can also show wander in the scope’s timebase◦PLL recovery can model what a real data receiver will seeIt can track and remove low-frequency effects, allowing you to “see through” to the jitter that really contributes to eye closur e ◦Explicit-Clock is appropriate if your design uses a forwarded clockMake sure your probes are deskewedHints for looking at Spread-Spectrum Clock•If you don’t want to see the SSC effects, use TIE and PLL clock recovery with a bandwidth of at least 1 MHz. A Type-II (2nd-order) PLL will track out the SSC more effectively than a Type-I PLL.•If you do want to observe the SSC profile:◦Use a Period measurement and turn on a 3rd-order low-pass filter(in DPOJET) with abandwidth of 200 kHzBecause Period trends accentuate high frequency noise, the low-frequency SSC trend will be obscured if you don’t use a filter You can’t use a Frequency measurement directly. The combination of filtering and the reciprocal operation (Freq = 1/Per) cau se distortion in the resulting waveshape. (This is a mathematical fact, not a DPOJET defect.)◦If you use a TIE measurement, you’ll see modulation that looks like a sine wave. This is normal. It’s because TIE measures phase modulation, which is the integral of frequency. It turns out that the integral of a triangle wave looks very much like a sine wave.误码率与噪声分析Anatomy of a Serial Data LinkComplete LinkReceiverChannel+-+-+-+-+-+-+-+-E q u a l i z e rP r e -E m p h a s i sTransmitterAspirational goal: 0 errorsPractical Goal: Bit Error Rate < Target BER•Since BER is the ultimate goal, why not measure it directly?Serial Data Link Integrity = Bit Error Rate•Bit Error Ratio Testers (BERTs) are the tools for measuring BER directly •Why not use ONLY BERTs for Serial Data Link Analysis?◦Difficult to model/emulate equalizer◦Measurements could take a very long time◦Instruments are very expensive and not all that flexible◦Does not analyze the root causes of the impairments of the links•Alternative approach: use a scope and advanced analysis tools ◦Easily move from Compliance to Debug◦Better equipped to identify root causes of eye closure◦Equalizer can easily be modeled◦More cost effective◦Faster throughputWhy Measure Jitter and Noise?▪Link Model: Transmitter + Channel + Receiver▪Transmitter generates a stream of symbols▪Receiver uses a slicer to make a decision on the transmitted symbol▪The Bit Decision is made at a certain time (t) of the symbol interval and a comparison of the sliced data to a threshold (v) is performed ▪Jitter impairs the time slicing position▪Noise impairs the decision threshold?Jitter combined with Noise Analysis is a better predictor of BER performance!A Quick Look at Jitter and Noise Duality•Jitter analysis evaluates a waveform in the horizontal dimension based on when the waveform crosses a horizontal reference line.•Jitter decomposition is based on spectral analysis of Time Interval Error vs. time◦Individual jitter componentscan be separated (i.e.PJ, RJ, DDJ, etc.)◦TJ can then be estimated at atarget BER level ▪Noise evaluates along a vertical dimension on the basis ofcrossings of a vertical referenceline at some percentage of the unit interval (usually 50%).▪Noise decomposition is based on spectral analysis of voltage error vs. time–Individual noise components canbe separated (i.e. PN,RN, DDN, etc.)–TN can then be estimated at atarget BER level抖动和噪声的解析•Jitter and Noise Decomposition provide deep insight into BERFull Jitter Analysis vs. Mask Testing•Jitter separation analysis is able to extrapolate total jitter or eye closure at various Bit Error Rates at a specific voltage threshold but it doesn’t reveal the statistical eye closure at any other voltage.•Conventional mask testing considers both time and voltage , but cannot extrapolate eye closure at low BER.Can we combine the best of both?41Statistical Jitter + Noise Analysis•By jointly analyzing Jitter and Noise, behavior at all points in the eye can be extrapolated at low BER•The methodology is analogous to current jitter analysis, but is performed across both dimensions of the eye◦Jitter and noise are separated into components (Random, Periodic, Data-Dependent,…)◦The components are reassembled into a model that allows accurate extrapolation.42Timing-Induced Jitter•Since jitter is defined as a shift in an edge’s time relative to its expected position, it is easy to think of jitter as being caused by horizontal (chronological) displacement.•Note that the displaced edge (green) has not moved vertically in this example.43Noise-Induced Jitter•Consider a burst of voltage noise (right) that displaces a waveform vertically.◦In this case, the displaced edge (green) has not moved horizontally.•The jitter as measured at the chosen reference voltage is identical in these cases!◦So, why should we care?44Noise-to-Jitter (AM-to-PM) Conversion•Since waveform transitions are never instantaneous, the slope (slew rate) of the edge acts as a gain constant that controls how effectively noise is converted to “observed jitter”.•We can think of RJ as being composed of two components.◦Horizontally induced: RJ(h)◦Vertically induced: RJ(v)•Since these two components are uncorrelated with each other, they add in the RSS sense:RJ=RJ(h)2+RJ(v)2•Similarly, PJ can be decomposed into PJ(h) and PJ(v) based on root cause•We measure noise at a reference point in the bit interval (usually 50%)•If slew rate isn’t zero, jitter (horizontal displacement) causes observed noise•So as with RJ, RN can be decomposed into components:◦Horizontally induced: RN(h)◦Vertically induced: RN(v)•Similarly, PN can be decomposed into PN(h) and PN(v) based on root causeNoise to Jitter and Jitter to Noise ConversionConsider: an “ideal” edge in a patternactually has two impairments:◦Jitter(h) (see the blue trace)INTROD UCTION –and Noise(note that both of Jitter and Noise result in jitter on edge)The Combined response (bottomright) includes the jittercaused by noiseNon-impaired bit edgeWe can separate the noisecontribution of jitter for diagnosticpurposes by breaking RJ intoRJ(v) and RJ(h)DPOJET and 80SJNB are the only tool that will show you this separation, and thus give youan important troubleshooting hint: e.g. is it crosstalk causing trouble, or the clocks?48Theory: Construction of the BER Eye •Consider a very simple pattern: 7 bit repeating•Overlay multiple segments of the 7-bit pattern. Each one has noise and jitter, so although the bit pattern is clear, they follow many slightly different paths:•Average many pattern repeats together. Everything that is uncorrelated with the pattern averages out. What remains is called the ‘correlated waveform’.◦This waveform fully characterizes DDJ, DCD, DDN, ISI –all data dependent effects•The correlated waveform can be snipped into individual bits and overlaid to form an eye diagram, using the recovered clock as the alignment reference. This forms the ‘correlated eye’:•Spectral jitter separation is used to find PDFs of the random and periodic jitter.•The RJ and PJ PDFs are convolved to find the uncorrelated jitter PDF (red)• A similar analysis of the noise yields the uncorrelated noise PDF (blue)◦Care must be taken to properly account for AM-to-PM and PM-to-AM conversion in these steps; otherwise some noise or jitter would be ‘double-counted’.•Two-dimensional convolution is used to create a joint PDF of uncorrelated jitter + noise. (We can call this the ‘jitter/noise set’)•The jitter/noise set is convolved (two-dimensionally) with the correlated eye for the ‘1’ bits to get the overall(correlated + uncorrelated) PDF for ‘1’ bits•The ‘1’ bit PDF is integrated vertically (from bottom to top) to get the ‘1’ bit CDF (Cumulative Distribution Function)◦In this color-graded view, each color represents a particular BER level•A similar treatment for ‘0’ bits yields the ‘0’ bit CDF54Theory: Construction of the BER Eye –Conclusion•The ‘1’ bit and ‘0’ bit CDFs are added to get the overall “BER Eye”◦ A particular BER contour can be found in the 3D version of this plot by slicing it horizontally, or by extracting a specific color on either version◦Since this ‘eye’ looks rather unconventional, DPOJET extracts the3D ViewColor-Graded View。

眼图详解关于眼图的基本知识1、眼图的作用数字信号的眼图可以体现数字信号的整体特征，能够很好地评估数字信号的质量，因而眼图的分析是数字系统信号完整性分析的关键之一。

2、眼图的形成串行数据的传输由于通讯技术发展的需要，特别是以太网技术的爆炸式应用和发展，使得电子系统从传统的并行总线转为串行总线。

串行信号种类繁多，如PCI Express、SPI、USB 等，其传输信号类型时刻在增加。

相比并行数据传输，串行数据传输的整体特点如下：1)信号线的数量减少，成本降低2)消除了并行数据之间传输的延迟问题3)时钟是嵌入到数据中的，数据和时钟之间的传输延迟也同样消除了4)传输线的PCB 设计也更容易些5)信号完整性测试也更容易实际中，描述串行数据的常用单位是波特率和UI，串行数据传输示例如下：串行数据传输示例例如，比特率为3.125Gb/s 的信号表示为每秒传送的数据比特位是3.125G 比特，对应的一个单位间隔即为1UI。

1UI表示一个比特位的宽度，它是波特率的倒数，即1UI=1/（3.125Gb/s）=320ps。

现在比较常见的串行信号码形是NRZ 码，因此在一般的情况下对于串行数据信号，我们的工作均是针对NRZ 码进行的。

由于示波器的余辉作用，将扫描所得的每一个码元波形重叠在一起，从而形成眼图。

眼图中包含了丰富的信息，从眼图上可以观察出码间串扰和噪声的影响，体现了数字信号整体的特征，从而可以估计系统优劣程度，因而眼图分析是高速互连系统信号完整性分析的核心。

另外也可以用此图形对接收滤波器的特性加以调整，以减小码间串扰，改善系统的传输性能。

眼图实际上就是数字信号的一系列不同二进制码按一定的规律在示波器屏幕上累积后的显示，简单地说，由于示波器具有余辉功能，只要将捕获的所有波形按每三个比特分别地叠加累积(如上图所示)，从而就形成了眼图。

目前，一般均可以用示波器观测到信号的眼图，其具体的操作方法为：将示波器跨接在接收滤波器的输出端，然后调整示波器扫描周期，使示波器水平扫描周期与接收码元的周期同步，这时示波器屏幕上看到的图形就称为眼图。

基于眼动分析的玩具视觉感知形式研究1. 引言1.1 研究背景在当前快速发展的玩具市场中，越来越多的设计师和制造商开始意识到玩具的视觉感知形式对于用户体验的重要性。

传统的玩具设计往往只注重外观与功能，忽视了用户对于视觉感知的需求和反应。

如何利用科学的方法来研究玩具的视觉感知形式，以提升用户体验成为一个亟待解决的问题。

1.2 研究目的研究目的是通过眼动分析技术来探究玩具视觉感知形式的特点和规律，从而为玩具设计提供科学依据和指导。

通过研究玩具在用户眼睛注视过程中的注意点和注视路径，我们可以更准确地了解用户对玩具的视觉注意偏好，进而优化玩具的外观、色彩和形状设计。

通过分析不同用户群体在视觉感知上的差异，可以为不同年龄段和性别的用户提供个性化的玩具设计方案。

通过研究玩具的视觉感知形式，我们可以深入探讨玩具对儿童认知、情感和创造力发展的影响，从而推动玩具设计行业的创新和发展。

通过本研究，我们旨在探索眼动分析技术在玩具设计领域的应用潜力，为提升玩具的视觉吸引力和用户体验提供科学的方法和指导。

1.3 研究方法在本研究中，我们采用了眼动追踪技术作为主要研究方法，以探究玩具视觉感知形式与眼动行为之间的关系。

眼动追踪技术是通过追踪被试者眼睛的运动轨迹和注视点来获取视觉信息的一种有效手段。

通过这项技术，我们可以分析被试者在观察玩具时的注意力分布、注视时长、扫视路径等眼动参数，从而揭示玩具设计对用户注意力的影响。

本研究采用了实验方法，首先设计了实验方案，在实验中设定了一系列任务和情境，以引导被试者对玩具进行观察。

通过眼动追踪仪器记录被试者的眼动行为数据，我们可以详细了解被试者对不同类型玩具的视觉感知方式，为玩具设计提供依据。

除了眼动追踪技术，我们还将结合问卷调查、访谈等定性研究方法，以便综合分析实验结果，进一步探究玩具视觉感知形式对用户体验的影响。

通过多种研究方法的综合运用，我们将全面而深入地探讨基于眼动分析的玩具视觉感知形式研究。

一文看懂数字定时：时钟信号、抖动、迟滞和眼图通过本文可以了解时钟信号的数字定时以及诸如抖动、漂移、上升时间、下降时间、稳定时间、迟滞和眼图等常用术语。

本教程是仪器基础教程系列的一部分。

1. 时钟信号发送数字信号其实发送的就是一串由0或1组成的数字序列。

然而，与不同设备进行通信时，定时信息要与发送的位相关联。

数字波形作为时钟信号的参考。

您可以将时钟信号看成是一个指挥者，它为数字电路系统的各个部分提供定时信号，使每个过程都可在精确的时间点触发。

时钟信号是具有固定周期的方波。

周期是指一个时钟边沿到下一个同类时钟边沿之间的时间间隔，最常用的方式是一个上升沿到下一个上升沿之间的时间间隔。

时钟的频率等于时钟周期的倒数。

图1. 数字波形作为时钟信号的参考，时钟信号具有固定周期，在数据传输过程中用固定的时间间隔来同步数字信号发射器和接收器。

时钟信号的占空比是波形处于所占的时间比。

图2展示了两个具有不同占空比的波形的区别您可以发现占空比为30%的波形处于的时间少于占空比为50%的波形。

图2.信号的占空比是指波形处于的时间百分比。

时钟信号用于在数据传输过程中同步数字信号发射器和接收器。

比如，发射器可以在时钟信号的每个上升沿发送一个数据位，接收器可使用相同的时钟读取数据。

在这种情况下，设备的确定边沿是上升沿(从低电平到高电平)。

对于其他设备则可能是下降沿(从高电平到低电平)。

时钟的确定边沿又称为有效时钟边沿。

数字信号发射器在每个有效时钟边沿触发新的数据发送，而接收器则在每个有效时钟边沿上进行采样。

后来的设备开始同时使用时钟的上升验和下降沿;这种设备被称为双倍数据速率传输(DDR)设备。

事实上，数据传输对于有效边沿有短暂的短延;这种延时称为时钟到输出时间。

当接收器依据采集时钟接收数据时，我们需要注意两个定时参数，以确保接收数据的可靠性。

建立时间(ts)是指数据连续处于有效逻辑电平且接收器准备好接收输入信号所需的时间。

保持时间(tH)是指接收器采样后，数据发生变化前需要保持在原有状态的时间。

Agilent——眼图、抖动、相噪2009-02-25 22:31随着数据速率超过Gb/s水平，工程师必须能够识别和解决抖动问题。

抖动是在高速数据传输线中导致误码的定时噪声。

如果系统的数据速率提高，在几秒内测得的抖动幅度会大体不变，但在位周期的几分之一时间内测量时，它会随着数据速率成比例提高，进而导致误码。

新兴技术要求误码率(BER)，亦即误码数量与传输的总码数之比，低于一万亿分之一(10-12)。

随着数据通信、总线和底板的数据速率提高，市场上已经出现许多不同的抖动检定技术，这些技术采用各种不同的实验室设备，包括实时数字示波器、取样时间间隔分析仪(TIA)、等时取样示波器、模拟相位检波器和误码率测试仪(BERT)。

为解决高数据速率上难以解决的抖动问题，工程师必需理解同步和异步网络中使用的各种抖动分析技术本文重点介绍3 Gb/s以上新兴技术的数据速率。

低于3 Gb/s的实时示波器可以捕获连续的数据流，可以同时在时域和频域中分析数据流；在更高的数据速率上，抖动分析要更具挑战性。

本文将从数字工程师的角度，介绍应对SONET/SDH挑战的各种经验。

抖动分析基本上包括比较抖动时钟信号和参考时钟信号。

参考时钟是一种单独的黄金标准时钟，或从数据中重建的时钟。

在高数据速率时，分析每个时钟的唯一技术是位检测和误码率测试；其它技术则采用某种取样技术。

如图1所示，眼图是逻辑脉冲的重叠。

它为测量信号质量提供了一种有用的工具，即使在极高的数据速率时，也可以在等时取样示波器上简便生成。

边沿由‘1’到‘0’转换和‘0’到‘1’转换组成，样点位于眼图的中心。

如果电压(或功率)高于样点，则码被标为逻辑‘1’；如果低于样点，则标为‘0’。

系统时钟决定着各个位的样点水平位置。

图1: 具有各项定义的眼图E1是逻辑‘1’的平均电压或功率电平，E0是逻辑‘0’的平均电压或功率电平。

参考点t = 0在左边的交点进行选择，右边的交点及其后是位周期TB。