电子信息工程专业英语课文翻译

基础电子学电子学衍生于对电力的研究和应用，是工程学和应用物理学的领域。

电力涉及力的产生，传输与使用金属导体。

电子学利用电子不同的运动方式及通过供气材料，如硅与锗等半导体，其他设备如太阳能电池，LED，微波激射器，激光及微波管等实现。

电子学应用于包括广播、雷达、电视、卫星系统传输，导航辅助设备系统，控制系统，空间探测设备，微型设备如电子表，许多电气设备和电脑等方面。

1.电子学的开端电子学的历史始于20世纪，包括三个关键元素：真空管，晶体管和集成电路。

19世纪早期是理论和发明取得重大发展的时代。

发现了红外线和紫外线。

道尔顿在1808年提出了原子理论。

在1840年之前就发现了热电效应、电解效应和光电效应。

20年之间相继产生了工作在低压下的放电管，辉光放电，新型电池及早期的扩音器。

因此，在1800—1875年之间，发现了基本的物理现象，电话，留声机，麦克风及扬声器等在实际应用中达到了极致。

至于19世纪末期，无线电报，磁记录，阴极射线示波器等都被发明了。

20世纪早期也见证了现代电子技术的开端。

1880年爱迪生发明了白炽灯成为现代电子领域的历史先驱者。

他发现有微弱的电流从加热的灯丝流向真空管内附着的金属板。

这就是众所周知的“爱迪生效应”。

如果使用了一个非电器的热源，注意到电池仅是必要的用来加热灯丝使电子移动。

1904年，约翰利用爱迪生效应发明了二极管，李.德.佛列思特紧接着在1906年发明了三极管。

这些真空管设备使电子能源控制的放大及传输成为可能。

20世纪初真空管的引入使现代电子学快速成长。

采用真空管让信号的控制成为可能，这是早期的电报电话电路不可能实现的，也是早期用高压电火花产生无线电波的发射机所不能实现的。

电子管首先应用于无线通信。

Guglielmo Marconi于1896年开辟了无线电报的发展，于1901年实现了远距离广播交流。

早期的收音机包括了无线电报（摩尔斯电码信号传输）或收音机电话（语音留言）。

电子信息工程专业英语课文翻译Unit20译文Unit 20 人为错误和系统设计Unit 20-1第一部分：从灾难中学习虽然泰坦尼克号和兴登堡的灾难已经过去了几十年，但它们却开始引起人们对于现代系统安全工程的极大关注。

两者都是当时规模最大的，最先进的技术，相当于今天正在开发并用于许多行业，对安全要求很高的基于计算机控制的系统。

这些灾难的例子最可怕之处也许不是那些在事后分析中看到的明显错误，而是它们和近期所发生事故之间的相似之处。

泰坦尼克号沉没最令人震惊之处在于卷入这起事件的人们竟自鸣得意到难以置信的地步。

爱德华时代末年是对工程和科学进步充满信心的年代，将如此多生命送上绝路的决定也许正是这种极度自信的结果。

然而，曾于1985年发现失事的皇家油轮泰坦尼克号的著名海洋学家罗伯特巴拉德博士，将泰坦尼克号和发生于1986年1月的挑战者号航天飞机失事这两起事件划上等号，指出正是对技术的过分自信和对自然环境力量的藐视导致了两起事件中指挥者的疏忽。

甚至官方报告也反映出一种毫无根据的自信，报告中讨论了救生艇准备的不足，除了委婉地指出这些救生艇已陈旧之外没有提出任何明显的批评。

同样地，报告提到望远镜，泛光灯和其他瞭望员的辅助设备达不到与泰坦尼克号的级别，却没有承认这些是设备上的缺陷。

“发生了令人遗憾的事故，但责任在其他方面”这样的基调可以在更近期的许多事故报告中看到。

泰坦尼克号的灾难也提出了一些技术问题。

船体外壳的结构是如何定下来的？船舱的数量，舱壁的高度和保证生存的所需设施是依赖什么分析数据决定的？也许对当时的技术水平来说提出这样的问题不公平，但是现代也有相似的案例。

例如，（我们可以）把（船）可能发生正面冲撞的假设与汽车制造厂对新车进行撞车试验这种几乎完全一样的假设相比较，对撞车试验的规定直到1997年才得到加强。

兴登堡事件还强调了其他一些同样挑战着现代工程师们的安全工程问题。

这些问题中最明显的一个可能就是改变设计后需对安全性做重新评估。

Unit 5 多址技术Unit 5-1第一部分：多址技术：频分多址、时分多址、码分多址多址方案用于使许多用户同时使用同一个固定带宽的无线电频谱。

在任何无线电系统中分配的带宽总是有限的。

移动电话系统的典型总带宽是50MHz ，它被分成两半用以提供系统的前向和反向连接。

任何无线网络为了提高用户容量都需要共享频谱。

频分多址（FDMA ）、时分多址（TDMA ）、码分多址（CDMA ）是无线系统中由众多用户共享可用带宽的三种主要方法。

这些方法又有许多扩展和混合技术，例如正交频分复用（OFDM ），以及混合时分和频分多址系统。

不过要了解任何扩展技术首先要求对三种主要方法的理解。

频分多址在FDMA 中，可用带宽被分为许多个较窄的频带。

每一用户被分配一个独特的频带用于发送和接收。

在一次通话中其他用户不能使用同一频带。

每个用户分配到一个由基站到移动电话的前向信道以及一个返回基站的反向信道，每个信道都是一个单向连接。

在每个信道中传输信号是连续的，以便进行模拟通信。

FDMA 信道的带宽一般较小（30kHz ），每个信道只支持一个用户。

FDMA 作为大多数多信道系统的一部分用于初步分割分配到的宽频带。

将可用带宽分配给几个信道的情况见图5.1和图5.2。

时分多址TDMA 将可用频谱分成多个时隙，通过分配给每一个用户一个时隙以便在其中发送或接收。

图5.3显示如何以一种循环复用的方式把时隙分配给用户，每个用户每帧分得一个时隙。

TDMA 以缓冲和爆发方式发送数据。

因此每个信道的发射是不连续的。

待发送的输入数据在前一帧期间被缓存，在分配给该信道的时隙中以较高速率爆发式发送出去。

TDMA 不能直接传送模拟信号因为它需要使用缓冲，因而只能用于传输数字形式的数据。

由于通常发送速率很高，TDMA 会受到多径效应的影响。

这导致多径信号引起码间干扰。

TDMA 一般与FDMA 结合使用，将可用的全部带宽划分为若干信道。

这是为了减少每个信道上的用户数以便使用较低的数据速率。

Unit 17 计算机和网络Unit 17-1第一部分：计算机的进展计算机和信息技术的进展计算机和信息技术的诞生可以追溯到许多世纪以前。

数学的发展引起了计算工具的发展。

据说17世纪法国的Blaise Pascal构建了第一台计算机。

在19世纪，常被推崇为计算之父的英国人Charles Babbage设计了第一台“分析机”。

该机器有一个机械的计算“工厂”，类似于19世纪早期的提花织布机，采用穿孔卡片来存储数字和处理要求。

Ada Lovelace和他（Charles Babbage）致力于设计并提出了指令序列的概念——程序。

到1871年Babbage逝世，这台机器还没有完成。

将近一个世纪以后，随着电子机械计算机的发展（程序）这一概念再次出现。

1890年，Herman Hollerith采用穿孔卡片帮助美国人口普查局分类信息。

与此同时，电报电话的发明为通信和真空管的发展奠定了基础。

这一电子器件能够用于存储二进制形式的信息，即开或关，1或0。

第一台数字电子计算机ENIAC（电子计数积分计算机，见图17.1）是为美国军队开发的，并于1946年完成。

普林斯顿的数学教授V on Neumann对（程序）这一概念作了进一步深入的研究，加入了存储计算机程序的思想。

这就是存储在计算机内存中的指令序列，计算机执行这些指令完成程序控制的任务。

图17.1 ENIAC：第一台数字化电子计算机从这一阶段开始，计算机和计算机编程技术迅速发展。

从真空管发展到晶体管，大大减小了机器（计算机）的尺寸和成本，并提高了可靠性。

接着，集成电路技术的出现又减小了计算机的尺寸（和成本）。

20世纪60年代，典型的计算机是基于晶体管的机器，价值50万美金，并需要一个大空调房和一名现场工程师。

现在相同性能的计算机只要2000做芯片的单个集成电路来实现。

微处理器和微型计算机的发展微型计算机随着集成电路（或芯片）技术的发展而发展。

这一技术使得计算机逻辑被“烧入”芯片层中。

英语原文：Life of LED-Based White Light SourcesThe interest for using light-emitting diodes (LEDs) for display and illumination applications has been growing steadily over the past few years. The potential for long life and reduced energy use are two key attributes of this rapidly evolving technology that have generated so much interest for its use in the above mentioned applications. Traditionally, the lamp life of light sources commonly used in illumination applications is determined by subjecting them to a predetermined on/off cycle until half the number of light sources cease to produce light. Unlike these sources, LEDs rarely fail catastrophically; instead, their light output slowly degrades over time. Even if an LED is technically operating and producing light, at some point the amount of light produced by the LED will be insufficient for the intended application. Therefore, the life of an LED should be based on the amount of time that the device can produce sufficient light for the intended application,rather than complete failure. Based on this argument, a recent publication from an industry group defines the life of an LED device or system for use in general lighting applications as the operating time, in hours, for the light output to reach 70% of its initial value.The most widely used white LEDs incorporate a layer of phosphor over a GaN-based, short-wavelength light emitter. Usually, the phosphor is embedded inside an epoxy resin that surrounds the LED die. Some portion of the short-wavelength radiation emitted by the LED is down-converted by the phosphor, and the combined radiation creates white light.Early white LEDs were packaged similar to the indicator-style colored LEDs, specifically 5 mm and SMD (surface mount devices). Although these products demonstrated the concept of a white light source, they did not produce sufficient light for display and illumination applications. Furthermore, these indicator-style white LEDs had a relatively short life, 5000–10 000h to reach 70% light level under normal operating conditions. To address the higher luminous flux requirements, manufacturers have started to commercialize high-power illuminator LEDs that are presently producing over one hundred times the flux compared to indicator-style white LEDs. The higher light output isachieved by using larger dies, higher drive currents,and improved heat extraction methods. In addition,some manufacturers are using better encapsulants to improve the life of white LEDs.There are several studies that have investigated the aging mechanisms of GaN-based LEDs. During the 1990s,Barton et al. investigated the degradation of GaN-based blue LEDs and showed that light output reduction over time occurred primarily due to the yellowing of the epoxy surrounding the die. In 2001, Narendran et al. observed that indicator-style white LED packages degraded very rapidly, with the LEDs reaching the 50% light output level within 6000 h. In that same study, it was shown that the chromaticity values of the white LEDs shifted toward yellow over time, and it was speculated that the yellowing of the epoxy was the main cause for light output degradation. Therefore, based on past studies,the primary reason for the degradation of indicator-style white LED packages is the yellowing of the epoxy that is caused by excessive heat at the p-n-junction of the LED. Some of the newer illuminator-style white LEDs use encapsulant materials that have lower photodegradation characteristics,and therefore have a lower degradation rate. However, there are factors such as the degradation of the die attaché epoxy, discoloration of the metal reflectors and the lead wires, and degradation of the semiconducting element that are influenced by heat, and these all contribute to the overall degradation of the white LED. Although the newer high-power white LEDs would have a lower degradation rate compared to the early indicator-style devices, it is the heat at the p-n-junction that most influences the degradation. The heat at the p-n-junction is caused by the ambient temperature and the ohmic heating at the bandgap.As stated earlier, long life is one key feature of LED technology that has attracted so many end-use communities. To benefit from the long-life feature, it is the final system that has to operate for a long time, not just the individual LED. As noted in past studies, heat at the p-n-junction is one of the key factors that determine the life of the white LED. Therefore, if systems are not properly designed with good thermal managemen techniques, even if they use long-life white LEDs the life of the final system would be short. Developing the relationship between junction temperature and life would be very usefulfor producing long-life systems.Although there are different methods available for estimating the junction temperature of LEDs, they are not very convenient,especially once the LEDs are integrated into a system . Furthermore, these methods are not direct; consequently, they are prone to erroneous results. Alternatively, it is much more convenient and direct to measure the heat at a location external to the LED package that is sufficiently close to the junction and where a temperature sensor can be directly attached. The temperature of this point should have a good relationship to the junction temperature. The point where a temperature sensor can be attached for this measurement could be the lead wire (cathode side) for the indicator-style LEDs and the board for high-power LEDs. Most manufacturers can recommend such a point,and we refer to this as the T-point in this manuscript.Since white LEDs in the marketplace are packaged differently, their ability to transfer heat from the die to the surrounding environment is different from product to product. Therefore, it is reasonable to assume that different products have different degradation rates as a function of heat. A graph that shows the life of the LED as a function of T-point temperature is extremely useful for system manufacturers to build reliable, long-lasting systems. By knowing how much impact heat has on the degradation rate or life of the LED, the system manufacturer can select components and drive parameters, including the amount of heat sink and drive current, for a product being designed for a given application.Therefore, the objective of the study presented in this manuscript was to investigate the relationship between the T-point temperature and life of a white LED. A second objective was to understand the degradation rate of different high-power white LED products presently available in the marketplace.To understand the relationship between the T-point temperature and life, one type of high-power white LED that is commonly available in the marketplace was selected. Several of these LEDs were subjected to a life test under different ambient temperatures. The details of the experimental setup are described in the following paragraphs.Because the different LED arrays have to operate at a particular ambient temperature, the arrays were placed inside specially designed, individual life-test chambers. The test chambers had two different functions: 1) to keep the ambient temperature constant for the LED arrays and 2) to act as light-integrating boxes for measuring light output. Each individual LED array was mounted at the center of the inside top surface of a life-test chamber. A photodiode attached to the center of the left panel continuously measured the light output.A small white baffle placed over the photodiode shielded it from the direct light, allowing only the reflected light to reach the photodiode. A resistance temperature detector placed on top of the baffle measured the chamber’s ambient temperature and controlled the heater that provided the necessary heat to the chamber through a temperature controller. The temperature in-side the box remained within ±1℃.The heater was attached to a raised aluminum plate with a matte-white cover that sat on the chamber floor. The temperature was estimated using a J-type thin wire thermocouple soldered to the T-point of white LED. For each chamber, an external LED driver controlled the current flow through the LEDs. All life-test were placed inside a temperature-controlled room. The life-test chambers were staggered vertically and horizontally to ensure that heat rising from the bottom chambers did not affect the chambers above them.The results of this study underscore the importance of packaging white LEDs using proper thermal management to maintain light output, and thereby extend system life. Heat at the p-n-junction is one of the main factors that affect the life of white LEDs. Therefore, knowing the relationship between life and heat would be very useful for manufacturers who are interested in developing reliable, long-lasting systems.Results from the first experiment—conducted under various ambient temperatures to understand the relationship between T-point temperature and life—indicate that life decreases with increasing temperature in an exponential manner. Results from the second experiment—conducted to understand how different commercial white LEDs perform under identical operating conditions—show a large variation in life among the different packages, indicating that the packages used different heat extraction techniques and materials.As part of ongoing research, we hope to further investigate how the different commercial LEDs are affected by heat and finally develop a family of curves that illustrate the relationship between life and T-point temperature for the different products.中文翻译：基于LED的白色光源的寿命在过去几年中利用发光二极管(led)显示和作为照明应用的技术一直在稳步增长。

Unit 12 生物识别技术Unit 12-1第一部分：指纹识别在所有的生物技术中，指纹识别是最早期的一种技术。

我们知道，每个人都有自己独特的、不可变更的指纹。

指纹是由手指表皮上的一系列峰谷组成的。

指纹的独特性是由这些峰谷的形状以及指纹的细节点所决定的。

指纹的细节点是指纹局部凸起处的一些特性，这些特性出现在凸起的分叉处或是凸起的截止处。

指纹匹配技术可以被分为两类：基于细节的指纹匹配技术和基于相关性的指纹匹配技术。

基于细节的指纹匹配首先要找出细节点，然后在手指上对应出与它们相关的位置，如图12.1所示。

但是，使用这种方法存在一些困难。

要精确地提取指纹的细节点是很困难的。

而且，这种方法不能很好地考虑指纹峰谷的整体形状。

基于相关性的指纹匹配技术可以解决部分基于细节的指纹匹配方法存在的问题，但它也存在一些自身的缺陷。

基于相关性的匹配技术需要给出已注册过的特征点的精确位置，并且该方法会受图像平移和旋转的影响。

图12.1 基于细节的指纹匹配基于细节的指纹匹配技术在匹配不同大小的细节模型时（未注册过的）会存在一些问题。

指纹上局部的凸起结构不能完全由指纹细节实现特征化。

我们可以尝试另一种表达指纹的方法，它可以获得更多的指纹局部信息并且得到固定长度的指纹编码。

于是，我们只需要计算两个指纹编码之间的欧几里得距离，匹配过程有望变得相对简单。

研发对于指纹图像中噪声更稳健并能实时提供更高精度的算法是重要的。

商用指纹（身份）认证系统对给定的错误接受率要求具有很低的错误拒绝率。

在这点上，任何一项简单的技术都很难实现。

我们可以从不同的匹配技术中汇总多个证据从而提高系统的总体精确度。

在实际应用中，传感器、采集系统、性能随时间的变化是关键因素。

为了评价系统性能，我们有必要对少数使用者在一段时间内进行现场试验。

每天我们可以从法医鉴定、出入口控制、驾驶证登记等多个方面的应用中采集并保存大量的指纹。

基于指纹的自动识别系统需要把输入的指纹与数据库中大量的指纹进行匹配验证。

1 The transistor is what started the evolution of the modern computer industry in motion.晶体管开启了现代电脑工业的革命2 The storage cell only requires one capacitor and one transistor, whereas a flip-flop connected in an array requires 6 transistors.存储单元仅需要一个电容和晶体管，并而不像触发器整列那样需要6个晶体管3 There has been a never ending series of new op amps released each year since then, and their performance and reliability has improved to the point where present day op amps can be used for analog applications by anybody.从此以后每年都有新系列的运放发布，他们的性能和可靠性得到了提升，如今任何人都能用运放来设计模拟电路。

4 This is capable of very high speed conversion and thus can accommodate high sampling rates, but in its basic form is very power hungry.它具有高速转换能力，从而能适应高速采样速率，但它的基本形式非常耗电。

5 During the “on” period , energy is being stored within the core material of the inductor in the form of flux.在”on”阶段，能量以涌浪形式存储在电感的核芯材料里面6 The design goal of frequency synthesizers is to replace multiple oscillators in a system, and hence reduce board space and cost.频率合成器的设计目标是取代系统中多个振荡器，从而减小板卡面积和成本。

电子信息工程专业英语教程第三版译者：唐亦林p32In 1945 H. W. Bode presented a system for analyzing the stability of feedback systems by using graphical methods. Until this time, feedback analysis was done by multiplication and division, so calculation of transfer functions was a time consuming and laborious task. Remember, engineers did not have calculators or computers until the '70s. Bode presented a log technique that transformed the intensely mathematical process of calculating a feedback system's stability into graphical analysis that was simple and perceptive. Feedback system design was still complicated, but it no longer was an art dominated by a few electrical engineers kept in a small dark room. Any electrical engineer could use Bode's methods find the stability of a feedback circuit, so the application of feedback to machines began to grow. There really wasn't much call for electronic feedback design until computers and transducers become of age.1945年HW伯德提出了一套系统方法，用图形化方法来分析反馈系统的稳定性。

电子信息工程专业英语课文翻译Unit11译文第一篇：电子信息工程专业英语课文翻译 Unit 11 译文Unit 11 数字图像处理Unit 11-1 第一部分：二维数字图像图像是表示一些物理参数空间分布的二维信号，典型的物理参数是光强，而更普通的是能量的任一种形式。

例如，运动图像以及多光谱的遥感图像是三维或者是更高维的信号。

现代数字技术使得处理多维信号成为可能，所使用的系统可从简单的数字电路到先进的并行计算机。

这种处理的目的可以分为3类：-图像处理：输入图像 输出图像用相机拍摄和冲洗照片-大自然的例子：水面上景色的反射，水雾中景色的失真，等等。

高级图像处理的应用例子包括：-司法科学：视频监控摄像机图像的增强，图像中的脸，指纹，DNA码等的自动识别和分类。

可视化。

例如：在我们制作一个三维物体的三维可视化之前，我们首先需要从二维图像中提取物体的信息。

图像增强，例如，减少噪声或图像锐化。

-模式识别，例如，图像中某种形状或纹理的自动检测。

-将数据量减少为更容易处置或解释的信息，例如将图像减小为一幅较简单的图像、一组对象或特征、或者一组测量结果。

-图像合成，如由二维照片重建三维场景。

-图像拼接。

当从同一个场景获取两种不同形态（类型）的图像时，将它们拼接起来涉及配准，其后是数据减少和图像合成。

-数据压缩。

为了缩小包含图像的计算机文件的大小，以及加快网络中图像传输的速度，数据压缩常常是必需的。

我们关心的只是数字图像处理，而不是模拟处理，理由是，模拟处理需要专用的硬件，这使得建立一个特殊的图像处理应用成为一项艰巨的任务。

此外，在许多图像处理领域中模拟硬件的使用正在迅速地成为过去，因为它常常能被更具灵活性的数字硬件（计算机）所取代。

但究竟什么是数字图像呢？数字图像获取与处理的示意图如图11.2所示。

顶部有某个成像设备，如摄像机，医疗扫描仪，或其它任何可将物理现实的量度转换为电信号的设备。

成像设备产生一个连续的电信号。

Unit 1 电子学：模拟和数字Unit 1-1第一部分：理想运算放大器和实际限制为了讨论运算放大器的理想参数，我们必须首先定义一些指标项，然后对这些指标项讲述我们所认为的理想值。

第一眼看运算放大器的性能指标表，感觉好像列出了大量的数值，有些是陌生的单位，有些是相关的，经常使那些对运放不熟悉的人感到迷惑。

对于这种情况我们的方法是花上必要的时间有系统的按照列出的次序阅读并理解每一个定义。

如果没有对每一项性能指标有一个真正的评价，设计人员必将失败。

目标是能够依据公布的数据设计电路，并确认构建的样机将具有预计的功能。

对于线性电路而言，它们与现在的复杂逻辑电路结构相比看起来较为简单，（因而在设计中）太容易忽视具体的性能参数了，而这些参数可极大地削弱预期性能。

现在让我们来看一个简单但很引人注意的例子。

考虑对于一个在50kHz频率上电压增益为10的放大器驱动10k 负载时的要求。

选择一个普通的带有内部频率补偿的低价运放，它在闭环增益为10时具有所要求的带宽，并且看起来满足了价格要求。

器件连接后，发现有正确地增益。

但是它只能产生几伏的电压变化范围，然而数据却清楚地显示输出应该能驱动达到电源电压范围以内2到3伏。

设计人员忽视了最大输出电压变化范围是受频率严格限制的，而且最大低频输出变化范围大约在10 kHz受到限制。

当然，事实上这个信息也在数据表上，但是它的实用性并没有受到重视。

这种问题经常发生在那些缺乏经验的设计人员身上。

所以这个例子的寓意十分明显：在开始设计之前总要花上必要的时间来描写全部的工作要求。

关注性能指标的详情总是有益的。

建议下面列出的具体的性能指标应该考虑：1. 在温度，时间和供给电压下的闭环增益的精确性和稳定性2. 电源要求，电源和负载阻抗，功率消耗3. 输入误差电压和偏置电流，输入输出电阻，随着时间和温度的漂移4. 频率响应，相位偏移，输出变化范围，瞬态响应，电压转换速率，频率稳定性，电容性负载驱动，过载恢复5. 线性，失真和噪声6. 输入，输出或电源保护要求，输入电压范围，共模抑制7. 外部补偿调整要求不是所有的指标项都是有关的，但要记住最初就考虑它们会更好，而不要被迫返工。

电子信息专业英语课文翻译1. Chapter 1 Introduction to Electronic Technology 电子技术简介 . Lesson 1 Development of Electronics 电子技术发展史 电子技术的历史是一个关于二十世纪的故事， 电子学的三个关键元件是真空管、 晶体管 和集成电路。

真空管也叫做 电子管， 它是一个密封的玻璃管， 在它里面， 电子在有真空隔离的电极之 间流动。

在20 (19X )世纪早期发明了真空管，随着真空管的发明，放大和传输电能成为 可能。

电子管的第一应用在于无线电通信。

在第二次世界大战之前， 随着越来越多的专门真 空管被制造出来用于各种用途，通信技术从而能得到了巨大的进步。

在20 世纪 20 年代时， 无线电广播呈天文数字地增长并且成为家庭娱乐的主要来源。

电视机是在1927 年发明，并 且最终得到了广泛的应用。

电视机作为一种电子设备， 其发展得益于在二次世界大战期间雷 达上的许多进步。

雷达利用无线电微波回声来测量一个物体的距离和方向，被用于检测飞机 和船只。

世界大战之后， 电子管被用于开发第一台计算机， 但是因为电子元件的尺寸， 所以这些 计算机是不切实际的。

在 1947 年，来自贝尔实验室的一组工程师们发明了晶体管，因为发 明了晶体管，他们获得了诺贝尔奖。

晶体管的功能类似于真空管， 但与真空管相比，它体积 小、重量轻、消耗功率低、 更加可靠和制造成本低。

在几乎所有的电子设备中晶体管取代了 真空管。

在 20 世纪 50 年代时，美国德州仪器公司发展出第一个集成电路。

第一个集成电路仅 包含了几个晶体管， 在随后的 20 世纪 70 年代中期， 出现了大规模集成电路和超大规模集成 电路。

超大规模集成电路技术允许我们在一个单芯片中构建一个包含有成千上万晶体管的系 统。

摄像机、手提电话和个人电脑仅仅是集成电路使之成为可能的一些设备实例。

电子信息工程专业英语教程第三版译者:唐亦林p32In 1945 H. W。

Bode presented a system for analyzing the stability of feedback systems by using graphical methods. Until this time, feedback analysis was done by multiplication and division，so calculation of transfer functions was a time consuming and laborious task. Remember, engineers did not have calculators or computers until the ’70s。

Bode presented a log technique that transformed the intensely mathematical process of calculating a feedback system’s stability into graphical analysis that was simple and perceptive. Feedback system design was still complicated, but it no longer was an art dominated by a few electrical engineers kept in a small dark room。

Any electrical engineer could use Bode's methods find the stability of a feedback circuit，so the application of feedback to machines began to grow。

第一单元 元件与定律A ．课文译文电阻器、电容器和电感器在电子电路中，电阻器、电容器和电感器是非常重要的元件。

电阻器和电阻电阻器是二端口元件。

电阻是阻止电流流动，更确切地说，是阻止电荷流动的能力。

在国际单位制中，电阻用欧姆来度量。

希腊字母Ω是欧姆的标准符号。

较大的电阻一般用千欧和兆欧来表示。

模拟这种特性常用的电路元件是电阻器。

图1.1表示电阻器的电路符号，R 表示电阻器的电阻值。

图1.1 电阻器的电路符号为了进行电路分析，我们必须在电阻器中指明电流和电压的参考方向。

如果我们选择关联参考方向，那么电压和电流之间的关系是：v =iR (1.1)这里 v 是电压，其单位是伏特， i 是电流，其单位是安培， R 是电阻，其单位是欧姆。

如果选择非关联参考方向，我们必须写成：v =－iR (1.2)用在公式（1.1）和（1.2）中的代数式就是著名的欧姆定律。

欧姆定律表示了电压作为电流的函数。

然而，要表示电流是电压的函数也是非常方便的。

欧姆定律是电阻两端的电压和电流间的代数关系。

电容器和电容电能可以存储在电场中，存储电能的装置叫电容器。

电容器存储电能的能力叫做电容。

图1.2表示电容器的电路符号。

电容的电路参数用字母C 表示，用法拉来度量。

因为法拉是相当大的电容量，实际上电容值通常位于皮法和微法之间。

图1.2 电容器的电路符号当电压随时间变化时，电荷的位移也随时间变化，引起了众所周知的位移电流。

在终端，位移电流和传导电流没有区别。

当电流参考方向和电压参考方向是关联参考方向时，电流正比于电容两端电压随时间的变化率的数学表达式为：dtdv C i = (1.3) 这里 i 的单位是安培，C 的单位是法拉，v 的单位是伏特， t 的单位是秒。

电感器和电感众所周知，电感是电子电路中的模块之一。

所有的线圈都有电感。

电感是抵抗流过线圈电流的任何变化的性质。

电感用字母L 表示，其单位是亨利。

图1.3表示一个电感器。

图1.3 电感器的电路符号当电流和电压的参考方向关联时，有dt diL v = (1.4)这里v 的单位是伏特，L 的单位是亨利，i 的单位是安培，t 的单位是秒。

Electronic power steering systemWhat it is?Electrically powered steering uses an electric motor to drive either the power steering hydraulic pump or the steering linkage directly. The power steering function is therefore independent of engine speed, resulting in significant energy savings.How it works?Conventional power steering systems use an engine accessory belt to drive the pump, providing pressurized fluid that operates a piston in the power steering gear or actuator to assist the driver.In electro-hydraulic steering, one electrically powered steering concept uses a high efficiency pump driven by an electric motor. Pump speed is regulated by an electric controller to vary pump pressure and flow, providing steering efforts tailored for different driving situations. The pump can be run at low speed or shut off to provide energy savings during straight ahead driving (which is most of the time in most world markets).Direct electric steering uses an electric motor attached to the steering rack via a gear mechanism (no pump or fluid). A variety of motor types and gear drives is possible. A microprocessor controls steering dynamics and driver effort. Inputs include vehicle speed and steering, wheel torque, angular position and turning rate.Working In Detail:A "steering sensor" is located on the input shaft where it enters the gearbox housing. The steering sensor is actually two sensors in one: a "torque sensor" that converts steering torque input and its direction into voltage signals, and a "rotation sensor" that converts the rotation speed and direction into voltage signals. An "interface" circuit that shares the same housing converts the signals from the torque sensor and rotation sensor into signals the control electronics can process. Inputs from the steering sensor are digested by a microprocessor control unit that alsomonitors input from the vehicle's speed sensor. The sensor inputs are then compared to determine how much power assist is required according to a preprogrammed "force map" in the control unit's memory. The control unit then sends out the appropriate command to the "power unit" which then supplies the electric motor with current. The motor pushes the rack to the right or left depending on which way the voltage flows (reversing the current reverses the direction the motor spins). Increasing the current to the motor increases the amount of power assist.The system has three operating modes: a "normal" control mode in which left or right power assist is provided in response to input from the steering torque and rotation sensor's inputs; a "return" control mode which is used to assist steering return after completing a turn; and a "damper" control mode that changes with vehicle speed to improve road feel and dampen kickback.If the steering wheel is turned and held in the full-lock position and steering assist reaches a maximum, the control unit reduces current to the electric motor to prevent an overload situation that might damage the motor. The control unit is also designed to protect the motor against voltage surges from a faulty alternator or charging problem.The electronic steering control unit is capable of self-diagnosing faults by monitoring the system's inputs and outputs, and the driving current of the electric motor. If a problem occurs, the control unit turns the system off by actuating a fail-safe relay in the power unit. This eliminates all power assist, causing the system to revert back to manual steering. A dash EPS warning light is also illuminated to alert the driver. To diagnose the problem, a technician jumps the terminals on the service check connector and reads out the trouble codes.Electric power steering systems promise weight reduction, fuel savings and package flexibility, at no cost penalty.Europe's high fuel prices and smaller vehicles make a fertile testbed for electric steering, a technology that promises automakers weight savings and fuel economy gains. And in a short time, electric steering will make it to the U.S., too. "It's just just a matter of time," says Aly Badawy, director of research and development for Delphi Saginaw SteeringSystems in Saginaw, Mich. "The issue was cost and that's behind us now. By 2002 here in the U.S. the cost of electric power steering will absolutely be a wash over hydraulic."Today, electric and hybrid-powered vehicles (EV), including Toyota's Prius and GM's EV-1, are the perfect domain for electric steering. But by 2010, a TRW Inc. internal study estimates that one out of every three cars produced in the world will be equipped with some form of electrically-assisted steering. The Cleveland-based supplier claims its new steering systems could improve fuel economy by up to 2 mpg, while enhancing handling. There are true bottom-line benefits as well for automakers by reducing overall costs and decreasing assembly time, since there's no need for pumps, hoses and fluids.Another claimed advantage is shortened development time. For instance, a Delphi group developed E-TUNE, a ride-and-handling software package that can be run off a laptop computer. "They can take that computer and plug it in, attach it to the controller and change all the handling parameters -- effort level, returnability, damping -- on the fly," Badawy says. "It used to take months." Delphi has one OEM customer that should start low-volume production in '99.Electric steering units are normally placed in one of three positions: column-drive, pinion-drive and rack-drive. Which system will become the norm is still unclear. Short term, OEMs will choose the steering system that is easiest to integrate into an existing platform. Obviously,greater potential comes from designing the system into an all-new platform. "We have all three designs under consideration," says Dr. Herman Strecker, group vice president of steering systems division at ZF in Schwaebisch Gmuend, Germany. "It's up to the market and OEMs which version finally will be used and manufactured." "The large manufacturers have all grabbed hold of what they consider a core technology," explains James Handy sides, TRW vice president, electrically assisted steering in Sterling Heights, Mich. His company offers a portfolio of electric steering systems (hybrid electric, rack-, pinion-, and column-drive). TRW originally concentrated on what it still believes is the purest engineering solution for electric steering--the rack-drive system. The system is sometimes refer to as direct drive orball/nut drive. Still, this winter TRW hedged its bet, forming a joint venture with LucasV arity. The British supplier received $50 million in exchange for its electric column-drive steering technology and as sets. Initial production of the column and pinion drive electric steering systems is expected to begin in Birmingham, England, in 2000.In 1995, according to Delphi, traditional hydraulic power steering systems were on 7596 of all vehicles sold globally. That 37-million vehicle pool consumes about 10 million gallons in hydraulic fluid that could be superfluous, if electric steering really takes off.The present invention relates to an electrically powered drive mechamsm for providing powered assistance to a vehicle steering mechanism. According to one aspect of the present invention, there is provided an electrically powered driven mechanism for providing powered assistance to a vehicle steering mechanism having a manually rotatable member for operating the steering mechanism, the drive mechanism including a torque sensor operable to sense torque being manually applied to the rotatable member, an electrically powered drive motor drivingly connected to the rotatable member and a controller which is arranged to control the speed and direction of rotation of the drive motor in response to signals received from the torque sensor, the torque sensor including a sensor shaft adapted for connection to the rotatable member to form an extension thereof so that torque is transmitted through said sensor shaft when the rotatable member is manually rotated and a strain gauge mounted on the sensor shaft for producing a signal indicative of the amount of torque being transmitted through said shaft. Preferably the sensor shaft is non-rotatably mounted at one axial end in a first coupling member and is non-rotatably mounted at its opposite axial end in a second coupling member, the first and second coupling members being inter-engaged to permit limited rotation there between so that torque under a predetermined limit is transmitted by the sensor shaft only and so that torque above said predetermined limit is transmitted through the first and second coupling members.Now, power steering systems of some cars have become the standard-setting, the whole world about half of the cars used to powersteering. With the development of automotive electronics technology, some cars have been using electric power steering gear, the car of the economy, power and mobility has improved. Electric power steering device on the car is a new power steering system device, developed rapidly in recent years both at home and abroad, because of its use of programmable electronic control devices, the flexibility in the same time there are also potential safety problems. In the analysis This unique product on the basis of the author of the characteristics of electronic control devices, security clearance just that the factors that deal with security measures, and discussed a number of concerns the safety of specific issues. The results show that : Existing standards can not meet the electric power steering device security needs and made the electric power steering device safety evaluation of the idea. Research work on the electric power steering device development and evaluation of reference value.电子动力转向系统电子动力转向系统是什么?电子动力转向系统是通过一个电动机来驱动动力方向盘液压泵或直接驱动转向联动装置。

Unit 2 集成电路Unit 2-1第一部分：集成电路数字逻辑和电子电路由称为晶体管的电子开关得到它们的（各种）功能。

粗略地说，晶体管好似一种电子控制阀，由此加在阀一端的能量可以使能量在另外两个连接端之间流动。

通过多个晶体管的组合就可以构成数字逻辑模块，如与门和触发电路等。

而晶体管是由半导体构成的。

查阅大学化学书中的元素周期表，你会查到半导体是介于金属与非金属之间的一类元素。

它们之所以被叫做半导体是由于它们表现出来的性质类似于金属和非金属。

可使半导体像金属那样导电，或者像非金属那样绝缘。

通过半导体和少量其它元素的混合可以精确地控制这些不同的电特性，这种混合技术称之为“半导体掺杂”。

半导体通过掺杂可以包含更多的电子（N型）或更少的电子（P型）。

常用的半导体是硅和锗，N型硅半导体掺入磷元素，而P型硅半导体掺入硼元素。

不同掺杂的半导体层形成的三明治状夹层结构可以构成一个晶体管，最常见的两类晶体管是双极型晶体管（BJT）和场效应晶体管（FET），图2.1给出了它们的图示。

图中给出了这些晶体管的硅结构，以及它们用于电路图中的符号。

BJT是NPN晶体管，因为由N—P—N掺杂硅三层构成。

当小电流注入基极时，可使较大的电流从集电极流向发射极。

图示的FET是N沟道的场效应型晶体管，它由两块被P型基底分离的N型组成。

将电压加在绝缘的栅极上时，可使电流由漏极流向源极。

它被叫做N沟道是因为栅极电压诱导基底上的N通道，使电流能在两个N区域之间流动。

图2.1所示的另一个基本的半导体结构是二极管，由N型和P型硅连接而成的结组成。

二极管的作用就像一个单向阀门，由于电流只能从P流向N。

可以构建一些特殊二极管，在加电压时可以发光，这些器件非常合适地被叫做发光二极管或LED。

这种小灯泡数以百万计地被制造出来，有各种各样的应用，从电话机到交通灯。

半导体材料上制作晶体管或二极管所形成的小芯片用塑料封装以防损伤和被外界污染。

在这封装里一些短线连接半导体夹层和从封装内伸出的插脚以便与（使用该晶体管的）电路其余部分连接。

Unit 8 光通信Unit 8-1第一部分：电磁频谱仔细研究表8.1中的频率表可以看到各种用于信息传输的光学技术的潜力。

人们所感兴趣的“现代”常规通信系统的信息传播速率通常相应于电话系统中的音频、商用广播系统中的无线电频率、或是最先进的视频节目分配系统中的数字电视数据率。

这些数据率通常低于几个吉赫兹（GHz）。

如果传输这样的信息不是将它加载到光纤上，而是加载在略高于最大速率的射频载波上，则此射频载波就会是厘米波或是波长更长一些的波。

用光载波则有很大的优越性。

一个明显的优点就是光纤的低损耗和方向性。

载波的数据率显然必须高于信息速率。

通信系统的一个基本原则是频率愈高，技术就愈复杂。

处理微波就比处理无线电波更困难。

随着波长减小到接近于电路元件的尺寸，电路单元就不再是集总的，导线可起到反射元件以及（或）天线的作用，集总单元则成为电磁谐振器。

这通常意味着当发送的信息较多时，代价也较高，因此在较高的信息率要求较高的频率这层意义上，要考虑传输信息的每个bps的成本问题。

于是，观察上述频率表得到的第一个结论就是，对于频率为数百特赫兹（THz）的光载波而言，信息的带宽在某种意义上是免费的。

就是说与大多数器件相比，光的波长是如此之小，以至于所用技术与电和微波有根本的不同。

一旦我们具备了这样的技术，则无论信息率有多高，再也没有必要改变载波了，因为载波频率高于任何现实信息率所能达到的程度。

不过带宽也不是完全免费的，因为编码器和解码器必须工作在相应于信息率的频率上，而系统其余部分大都只需要处理载波和调制。

如果一个元件可以工作在5⨯1014Hz的频率上，在这个频率信息偏移千分之一（相应于500吉赫兹的信息率）对器件的性能将没有什么影响。

因此，只要系统已经建立起来，大体上就可以随意升级系统而不会涉及常规系统中改变电磁载波所需付出的那种代价。

光波的宽频带一个结果就是光载波可以同时携带许多不同电话信号和电视节目等。

通常实现这种同时传输多路信息的过程（至少以同步格式实现）称为时分复用。

电子信息工程专业英语Part 1第一课关于电子技术一、课文习题参考答案Ⅰ. （1）alternating current circuits （2）semiconductor diodes（3）passive component（4）the combinatory logic electric circuit（5）rectification（6）Laplace transform（7）inductor（8）Fourier series and Fourier transformⅡ.（1）控制理论（2）场效应管三极管（3）布尔代数（4）稳压（5）相关性和功率谱密度（6）滤波器类型（7）模/数转换器（8）时序逻辑电路的分析与综合Ⅲ.(1)Electronics is a part of the larger field of electricity. The basic principles of electricity are also common to electronics. Modern advances in the field of computer, control system, communications have a close relationship with electronics. The field of electronics includes the electron tube, transistor, integrated circuit and so on.(2) Direct current circuits & Alternating current circuits,Analog electronics,Digital electronics,signal and systems,Circuit theory and design, Control theory, Microcontroller systems,Computer programming for engineering applications.(3) This curriculum mainly introduces the characteristics of semiconductor devices in linear application scope.The content involved in semiconductor diodes (PN junction diodes, special purpose diodes), transistors (field effects and bipolar transistors), signal amplifiers, practical amplifiers, biasing circuits, operational amplifiers circuit and other circuits (rectification, regulation and DC power supplies).(4) This partial studies take the basic electric circuit theory and the operational amplifier knowledge as the foundation. The main study goal is to enhance understanding of the electric circuit theory. Its main content includes the elementary theory in circuit theory (network functions, characteristic frequencies), types of filter (lowpass,bandpass), review of operational amplifiers (design of first and second order using operational amplifiers, cascade design), filter characteristics(Butterworth, Chebyshev, frequency transformations in design, sensitivity design of passive LC ladder filters and a brief introduction to switched capacitor filters).(5) Perfect.二、参考译文电子学的发展电子学是电学的一部分。