外文翻译----数字图像处理方法的研究(中英文)

The research of digital image processing technique

1Introduction

Interest in digital image processing methods stems from two principal application areas:improvement of pictorial information for human interpretation;and processing of image data for storage,transmission,and representation for autonomous machine perception.This chapter has several objectives:(1)to define the scope of the field that we call image processing;(2)to give a historical perspective of the origins of this field;

(3)to give an idea of the state of the art in image processing by examining some of the principal area in which it is applied;(4)to discuss briefly the principal approaches used in digital image processing;(5)to give an overview of the components contained in a typical,general-purpose image processing system;and(6)to provide direction to the books and other literature where image processing work normally is reporter.

1.1What Is Digital Image Processing?

An image may be defined as a two-dimensional function,f(x,y),where x and y are spatial(plane)coordinates,and the amplitude of f at any pair of coordinates(x,y)is called the intensity or gray level of the image at that point.When x,y,and digital image.The field of digital image processing refers to processing digital images by means of a digital computer.Note that a digital image is composed of a finite number of elements,each of which has a particular location and value.These elements are referred to as picture elements,image elements,pels,and pixels.Pixel is the term most widely used to denote the elements of a digital image.We consider these definitions in more formal terms in Chapter2.

Vision is the most advanced of our senses,so it is not surprising that images play the single most important role in human perception.However,unlike human who are limited to the visual band of the electromagnetic(EM)spectrum,imaging machines cover almost the entire EM spectrum,ranging from gamma to radio waves.They can operate on images generated by sources that human are not accustomed to associating with image.These include ultrasound,electron microscopy,and computer-generated images.Thus,digital image processing encompasses a wide and varied field of application.

There is no general agreement among authors regarding where image processing stops and other related areas,such as image analysis and computer vision,start. Sometimes a distinction is made by defining image processing as a discipline in which both the input and output of a process are images.We believe this to be a limiting and somewhat artificial boundary.For example,under this definition,even the trivial task of computing the average intensity of an image(which yields a single number)would not be considered an image processing operation.On the other hand, there are fields such as computer vision whose ultimate goal is to use computer to

emulate human vision,including learning and being able to make inferences and take actions based on visual inputs.This area itself is a branch of artificial intelligence(AI) whose objective is to emulate human intelligence.This field of AI is in its earliest stages of infancy in terms of development,with progress having been much slower than originally anticipated.The area of image analysis(also called image understanding)is in between image processing and computer vision.

There are no clear-cut boundaries in the continuum from image processing at one end to computer vision at the other.However,one useful paradigm is to consider three types of computerized processes is this continuum:low-,mid-,and high-ever processes.Low-level processes involve primitive operation such as image preprocessing to reduce noise,contrast enhancement,and image sharpening.A low-level process is characterized by the fact that both its input and output are images. Mid-level processing on images involves tasks such as segmentation(partitioning an image into regions or objects),description of those objects to reduce them to a form suitable for computer processing,and classification(recognition)of individual object. Amid-level process is characterized by the fact that its inputs generally are images, but its output is attributes extracted from those images(e.g.,edges contours,and the identity of individual object).Finally,higher-level processing involves“making sense”of an ensemble of recognized objects,as in image analysis,and,at the far end of the continuum,performing the cognitive function normally associated with vision. Based on the preceding comments,we see that a logical place of overlap between image processing and image analysis is the area of recognition of individual regions or objects in an image.Thus,what we call in this book digital image processing encompasses processes whose inputs and outputs are images and,in addition, encompasses processes that extract attributes from images,up to and including the recognition of individual objects.As a simple illustration to clarify these concepts, consider the area of automated analysis of text.The processes of acquiring an image of the area containing the text.Preprocessing that images,extracting(segmenting)the individual characters,describing the characters in a form suitable for computer processing,and recognizing those individual characters are in the scope of what we call digital image processing in this book.Making sense of the content of the page may be viewed as being in the domain of image analysis and even computer vision, depending on the level of complexity implied by the statement“making cense.”As will become evident shortly,digital image processing,as we have defined it,is used successfully in a broad rang of areas of exceptional social and economic value.The concepts developed in the following chapters are the foundation for the methods used in those application areas.

1.2The Origins of Digital Image Processing

One of the first applications of digital images was in the newspaper industry,when pictures were first sent by submarine cable between London and NewYork. Introduction of the Bartlane cable picture transmission system in the early1920s reduced the time required to transport a picture across the Atlantic from more than a

week to less than three hours.Specialized printing equipment coded pictures for cable transmission and then reconstructed them at the receiving end.Figure 1.1was transmitted in this way and reproduced on a telegraph printer fitted with typefaces simulating a halftone pattern.

Some of the initial problems in improving the visual quality of these early digital pictures were related to the selection of printing procedures and the distribution of intensity levels.The printing method used to obtain Fig.1.1was abandoned toward the end of1921in favor of a technique based on photographic reproduction made from tapes perforated at the telegraph receiving terminal.Figure1.2shows an images obtained using this method.The improvements over Fig.1.1are evident,both in tonal quality and in resolution.

FIGURE1.1A digital picture produced in FIGURE1.2A digital picture 1921from a coded tape by a telegraph printer made in1922from a tape punched With special type faces(McFarlane)after the signals had crossed the

Atlantic twice.Some errors are

Visible.(McFarlane)

The early Bartlane systems were capable of coding images in five distinct level of gray.This capability was increased to15levels in1929.Figure1.3is typical of the images that could be obtained using the15-tone equipment.During this period, introduction of a system for developing a film plate via light beams that were modulated by the coded picture tape improved the reproduction process considerably. Although the examples just cited involve digital images,they are not considered digital image processing results in the context of our definition because computer were not involved in their creation.Thus,the history of digital processing is intimately tied to the development of the digital computer.In fact digital images require so much storage and computational power that progress in the field of digital image processing has been dependent on the development of digital computers of supporting technologies that include data storage,display,and transmission.

The idea of a computer goes back to the invention of the abacus in Asia Minor, more than5000years ago.More recently,there were developments in the past two centuries that are the foundation of what we call computer today.However,the basis

for what we call a modern digital computer dates back to only the1940s with the introduction by John von Neumann of two key concepts:(1)a memory to hold a stored program and data,and(2)conditional branching.There two ideas are the foundation of a central processing unit(CPU),which is at the heart of computer today. Starting with von Neumann,there were a series of advances that led to computers powerful enough to be used for digital image processing.Briefly,these advances may be summarized as follow:

(1)the invention of the transistor by Bell Laboratories in1948;

(2)the development in the1950s and1960s of the high-level programming

languages COBOL(Common Business-Oriented Language)and FORTRAN (Formula Translator);

(3)the invention of the integrated circuit(IC)at Texas Instruments in1958;

(4)the development of operating system in the early1960s;

(5)the development of the microprocessor(a single chip consisting of the central

processing unit,memory,and input and output controls)by Inter in the early 1970s;

(6)introduction by IBM of the personal computer in1981;

(7)progressive miniaturization of components,starting with large scale integration

(LI)in the late1970s,then very large scale integration(VLSI)in the1980s,to the present use of ultra large scale integration(ULSI).

Figure1.3In1929from London to Cenerale Pershing

that New York delivers with15level tone equipments

through cable with Foch do not the photograph by decoration

Concurrent with these advances were development in the areas of mass storage and display systems,both of which are fundamental requirements for digital image processing.

The first computers powerful enough to carry out meaningful image processing

tasks appeared in the early1960s.The birth of what we call digital image processing today can be traced to the availability of those machines and the onset of the apace program during that period.It took the combination of those two developments to bring into focus the potential of digital image processing concepts.Work on using computer techniques for improving images from a space probe began at the Jet Propulsion Laboratory(Pasadena,California)in1964when pictures of the moon transmitted by Ranger7were processed by a computer to correct various types of image distortion inherent in the on-board television camera.Figure1.4shows the first image of the moon taken by Ranger7on July31,1964at9:09A.M.Eastern Daylight Time(EDT),about17minutes before impacting the lunar surface(the markers,called reseau mark,are used for geometric corrections,as discussed in Chapter5).This also is the first image of the moon taken by a U.S.spacecraft.The imaging lessons learned with ranger7served as the basis for improved methods used to enhance and restore images from the Surveyor missions to the moon,the Mariner series of flyby mission to Mars,the Apollo manned flights to the moon,and others.

In parallel with space application,digital image processing techniques began in the late1960s and early1970s to be used in medical imaging,remote Earth resources observations,and astronomy.The invention in the early1970s of computerized axial tomography(CAT),also called computerized tomography(CT)for short,is one of the most important events in the application of image processing in medical diagnosis. Computerized axial tomography is a process in which a ring of detectors encircles an object(or patient)and an X-ray source,concentric with the detector ring,rotates about the object.The X-rays pass through the object and are collected at the opposite end by the corresponding detectors in the ring.As the source rotates,this procedure is repeated.Tomography consists of algorithms that use the sensed data to construct an image that represents a“slice”through the object.Motion of the object in a direction perpendicular to the ring of detectors produces a set of such slices,which constitute a three-dimensional(3-D)rendition of the inside of the object.Tomography was invented independently by Sir Godfrey N.Hounsfield and Professor Allan M. Cormack,who shared the X-rays were discovered in1895by Wilhelm Conrad Roentgen,for which he received the1901Nobel Prize for Physics.These two inventions,nearly100years apart,led to some of the most active application areas of image processing today.

Figure1.4The first picture of the moon by a U.S. Spacecraft.Ranger7took this image on July31, 1964at9:09A.M.EDT,about17minutes before

Impacting the lunar surface.(Courtesy of NASA.)

中文翻译

数字图像处理方法的研究

1绪论

数字图像处理方法的研究源于两个主要应用领域:其一是为了便于人们分析而对图像信息进行改进；其二是为了使机器自动理解而对图像数据进行存储、传输及显示。

1.1数字图像处理的概念

一幅图像可定义为一个二维函数f(x,y)，这里x和y是空间坐标，而在任何一对空间坐标f(x,y)上的幅值f称为该点图像的强度或灰度。当x，y和幅值f为有限的、离散的数值时，称该点是由有限的元素组成的，没一个元素都有一个特定的位置和幅值，这些元素称为图像元素、画面元素或象素。象素是广泛用于表示数字图像元素的词汇。在第二章，将用更正式的术语研究这些定义。

视觉是人类最高级的感知器官，所以，毫无疑问图像在人类感知中扮演着最重要的角色。然而，人类感知只限于电磁波谱的视觉波段，成像机器则可覆盖几乎全部电磁波谱，从伽马射线到无线电波。它们可以对非人类习惯的那些图像源进行加工，这些图像源包括超声波、电子显微镜及计算机产生的图像。因此，数字图像处理涉及各种各样的应用领域。

图像处理涉及的范畴或其他相关领域(例如，图像分析和计算机视觉)的界定在初创人之间并没有一致的看法。有时用处理的输人和输出内容都是图像这一特点来界定图像处理的范围。我们认为这一定义仅是人为界定和限制。例如，在这个定义下，甚至最普通的计算一幅图像灰度平均值的工作都不能算做是图像处理。另一方面，有些领域(如计算机视觉)研究的最高目标是用计算机去模拟人类视觉，包括理解和推理并根据视觉输人采取行动等。这一领域本身是人工智能的分支，其目的是模仿人类智能。人工智能领域处在其发展过程中的初期阶段，它的发展比预期的要慢得多，图像分析(也称为图像理解)领域则处在图像处理和计算机视觉两个学科之间。

从图像处理到计算机视觉这个连续的统一体内并没有明确的界线。然而，在这个连续的统一体中可以考虑三种典型的计算处理(即低级、中级和高级处理)来区分其中的各个学科。低级处理涉及初级操作，如降低噪声的图像预处理，对比度增强和图像尖锐化。低级处理是以输人、输出都是图像为特点的处理。中级处理涉及分割〔把图像分为不同区域或目标物)以及缩减对目标物的描述，以使其更适合计算机处理及对不同日标的分类(识别)。中级图像处理是以输人为图像，但输出是从这些图像中提取的特征(如边缘、轮廓及不同物体的标识等)为特点的。最后，高级处理涉及在图像分析中被识别物体的总体理解，以及执行与视觉相关的识别函数(处在连续统一体边缘)等。

根据上述讨论，我们看到，图像处理和图像分析两个领域合乎逻辑的重叠区域是图像中特定区域或物体的识别这一领域。这样，在本书中，我们界定数字图

像处理包括输人和输出均是图像的处理，同时也包括从图像中提取特征及识别特定物体的处理。举一个简单的文本自动分析方面的例子来具体说明这一概念。在自动分析文本时首先获取一幅包含文本的图像，对该图像进行预处理，提取(分割)字符，然后以适合计算机处理的形式描述这些字符，最后识别这些字符，而所有这些操作都在本书界定的数字图像处理的范围内。理解一页的内容可能要根据理解的复杂度从图像分析或计算机视觉领域考虑问题。这样，本书定义的数字图像处理的概念将在有特殊社会和经济价值的领域内通用。在以下各章展开的概念是那些应用领域所用方法的基础。

1.2数字图像处理的起源

数字图像处理最早的应用之一是在报纸业，当时，图像第一次通过海底电缆从伦敦传往纽约。早在20世纪20年代曾引入Btutlane电缆图片传输系统，把横跨大西洋传送一幅图片所需的时间从一个多星期减少到3个小时。为了用电缆传输图片，首先要进行编码，然后在接收端用特殊的打印设备重构该图片。图1.1就是用这种方法传送并利用电报打印机通过字符模拟中间色调还原出来的图像。

这些早期数字图像视觉质量的改进工作，涉及到打印过程的选择和亮度等级的分布等问题。用于得到图1.1的打印方法到1921年底就被彻底淘汰了，转而支持一种基于光学还原的技术，该技术在电报接收端用穿孔纸带打出图片。图1.2就是用这种方法得到的图像，对比图1.1，它在色调质量和分辨率方面的改进都很明显。

图1.11421年由电报打印机采用特殊字图1.21922年在信号两次穿越大西洋后，符在编码纸带中产生的数字图像从穿孔纸带得到的数字图像，可以

(McFalsne)看出某些差错(McFalsne)

早期的Bartlane系统可以用5个灰度等级对图像编码，到1929年已增加到15个等级。图1.3所示的这种典型类型的图像就是用15级色调设备得到的。在这一时期，由于引入了一种用编码图像纸带去调制光束而使底片感光的系统，明显地改善了复原过程。

刚才引用的数字图像的例子并没有考虑数字图像处理的结果，这主要是因为没有涉及到计算机。因此，数字图像处理的历史与数字计算机的发展密切相关。事实上，数字图像要求非常大的存储和计算能力，因此数字图像处理领域的发展必须依靠数字计算机及数据存储、显示和传输等相关技术的发展。

计算机的概念可追溯到5000多年前中国算盘的发明。近两个世纪以来的一些发展也奠定了计算机的基础。然而，现代计算机的基础还要回溯到20世纪40年代由约翰·冯·诺依曼提出的两个重要概念:(l)保存程序和数据的存储器;(2)条件分支。这两个概念是中央处理单元(CPU)的基础。今天，它是计算机的心脏。从冯·诺依曼开始，引发了一系列重要技术进步，使得计算机以强大的功能用于数字图像处理领域。

简单说，这些进步可归纳为如下几点:

(1)1948年贝尔实验室发明了晶体三极管；

(2)20世纪50年代到20世纪60年代高级编程语言(如COBOL和FORTRAN)的开发；

(3)1958年得州仪器公司发明了集成电路(IC);

(4)20世纪60年代早期操作系统的发展;

(5)20世纪70年代Intel公司开发了微处理器(由中央处理单元、存储器和输入输出控制组成的单一芯片);

(6)1981年IBM公司推出了个人计算机;

(7)20世纪70年代出现的大规模集成电路(LI)所引发的元件微小化革命，20世纪80年代出现了YLSI(超大规模集成电路)，现在已出现了ULSI。

图1.3在1929年从伦敦到纽约用15级色调设备通过电缆

传送的Cenerale Pershing和Foch的未经修饰的照片伴随着这些技术进步，大规模的存储和显示系统也随之发展起来。这两者均是数字图像处理的基础。

第一台可以执行有意义的图像处理任务的大型计算机出现在20世纪60年代早期。数字图像处理技术的诞生可追溯至这一时期这些机器的使用和空间项目的开发，这两大发展把人们的注意力集中到数字图像处理的潜能上。利用计算机技术改善空间探测器发回的图像的工作，始于1964年美国加利福尼亚的喷气推进实验室。当时由“旅行者7号”卫星传送的月球图像由一台计算机进行了处理，以校正航天器上电视摄像机中各种类型的图像畸变。图1.4显示了由“旅行者7号”于1954年7月31日上午(东部白天时间)9点09分在光线影响月球表面前约17分钟时摄取的第一张月球图像[痕迹(称为网状痕迹)用于几何校正，在第5章将讨论该间题]，这也是美国航天器取得的第一幅月球图像。“旅行者7号”传

送的图像可作为改善的增强和复原图像(例如来自“探索者”登月一飞行、“水手号”系列空间探渊器及阿波罗载人登月飞行的图像)方法的基础。

进行空间应用的同时，数字图像处理技术在20世纪60年代末和20世纪70年代初开始用于医学图像、地球遥感监测和天文学等领域。早在20世纪70年代发明的计算机轴向断层术(CAT)[简称计算机断层(CT)]是图像处理在医学诊断领域最重要的应用之一。计算机轴向断层术是一种处理方法，在这种处理中，一个检测器环围绕着一个物体(或病人)，并且一个x射线源(与检测器环同心)绕着物体旋转。X射线穿过物体并由位于对面环中的相应检测器收集起来。当X射线源旋转时，重复这一过程。断层技术由一些算法组成，该算法用感知的数据去重建通过物体的“切片”图像。当物体沿垂直于检测器的方向运动时就产生一系列这样的“切片”，这些切片组成了物体内部的再现图像。断层技术是由Godfrey N. Hounsfield先生和Allan M.Cormack教授发明的，他们共同获得了1979年诺贝尔医学奖。X射线是在1895年由威廉·康拉德·伦琴发现的，由于这一发现，他获得了I901年诺贝尔物理学奖。这两项发明相差近100年。它们在今天引领着图像处理某些最活跃的应用领域。

图1.4美国航天器传送的第一张月球照片，“旅行者7号”

卫星1964年7月31日9点09分(东部白天时间)在

光线影响月球表面前17分钟时摄取的图像

机械手机械设计论文中英文资料对照外文翻译

中英文资料对照外文翻译 机械设计 摘要： 机器由机械和其他元件组成的用来转换和传输能量的装置。比如：发动机、涡轮机、车、起重机、印刷机、洗衣机和摄影机。许多机械方面设计的原则和方法也同样适用于非机械方面。术语中的“构造设计”的含义比“机械设计”更加广泛，构造设计包括机械设计。在进行运动分析和结构设计时要把产品的维护和外形也考虑在机械设计中。在机械工程领域中，以及其它工程领域，都需要机械设备，比如：开关、凸轮、阀门、船舶以及搅拌机等。 关键词：设计流程设计规则机械设计 设计流程 设计开始之前就要想到机器的实用性，现有的机器需要在耐用性、效率、重量、速度，或者成本上得到改善。新的机器必需能够完全或部分代替以前人的功能，比如计算、装配、维修。 在设计的初级阶段，应该充分发挥设计人员的创意，不要受到任何约束。即使有一些不切实际的想法，也可以在设计的早期，即在绘制图纸之前被改正掉。只有这样，才不致于阻断创新的思路。通常,必须提出几套设计方案,然后进行比较。很有可能在这个计划最后指定使用某些不在计划方案内的一些想法的计划。 一般当产品的外型和组件的尺寸特点已经显现出来的时候，就可以进行全面的设计和分析。接着还要客观的分析机器性能、安全、重量、耐用性，并且成本也要考虑在内。每一个至关重要的部分要优化它的比例和尺寸，同时也要保持与其它组成部分的平衡。 选择原材料和工艺的方法。通过力学原理来分析和实现这些重要的特性，如稳定和反应的能量和摩擦力的利用，动力惯性、加速度、能量；包括材料的弹性强度、应力和刚度等物理特性，以及流体的润滑和驱动器的流体力学。设计的过程是一个反复与合作的过程，无论是正式的还是非正式的，对设计者来说每个阶段都很重要。。产品设计需要大量的研究和提升。许多的想法,必须通过努力去研究成为一种理念,然后去使用或放弃。

英文文献翻译

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数字图像处理

数字图像处理(MATLAB版) 实验指导书 (试用版) 本实验指导书配合教材和课堂笔记中的例题使用 姚天曙编写 安徽农业大学工学院 2009年4月试行

目录 实验一、数字图像获取和格式转换 2 实验二、图像亮度变换和空间滤波 6 实验三、频域处理7 实验四、图像复原9 实验五、彩色图像处理10 实验六、图像压缩11 实验七、图像分割13 教材与参考文献14

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机械专业外文翻译中英文翻译

外文翻译 英文原文 Belt Conveying Systems Development of driving system Among the methods of material conveying employed，belt conveyors play a very important part in the reliable carrying of material over long distances at competitive cost．Conveyor systems have become larger and more complex and drive systems have also been going through a process of evolution and will continue to do so．Nowadays，bigger belts require more power and have brought the need for larger individual drives as well as multiple drives such as 3 drives of 750 kW for one belt(this is the case for the conveyor drives in Chengzhuang Mine)．The ability to control drive acceleration torque is critical to belt conveyors’ performance．An efficient drive system should be able to provide smooth，soft starts while maintaining belt tensions within the specified safe limits．For load sharing on multiple drives．torque and speed control are also important consideratio ns in the drive system’s design. Due to the advances in conveyor drive control technology，at present many more reliable．Cost-effective and performance-driven conveyor drive systems cov ering a wide range of power are available for customers’ choices[1]. 1 Analysis on conveyor drive technologies 1．1 Direct drives Full-voltage starters．With a full-voltage starter design，the conveyor head shaft is direct-coupled to the motor through the gear drive．Direct full-voltage starters are adequate for relatively low-power, simple-profile conveyors．With direct fu11-voltage starters．no control is provided for various conveyor loads and．depending on the ratio between fu11- and no-1oad power requirements，empty starting times can be three or four times faster than full load．The maintenance-free starting system is simple，low-cost and very reliable．However, they cannot control starting torque and maximum stall torque；therefore．they are

数字图像处理模拟题(双语课)

Terms and concepts explanation RGB：Red Green Blue 三原色红绿蓝 CMYK：cyan magenta yellow black 青、粉红、黄、黑 HSI: hue saturation intensity 色调、饱和度、亮度 FFT fast fourier transform 快速傅里叶变换 CWT continuous wavelet transform 连续小波变换 DCT discrete cosine transform 离散余弦变换 DFT discrete fourier transform 离散傅里叶变换 DWT discrete wavelet transform 离散小波变换 CCD charge-coupled device电荷耦合元件 Pixel a digital image is composed of a finite number of elements,each of which has a particular lication and value,these elements are called pixel 像素 DC component in frequency domain （direct current component）直流分量的频率域GLH The Gray Level Histogram 灰度直方图 Mather（basic）wavelet :a function (wave) used to generate a set of wavelets,母小波，用于产生小波变换所需的一序列子小波 Basis functions basis image : there i s only one set of αk for any given f(x), then the ψk (x) are called basis functions Multi-scale analysis多尺度分析 Gaussian function:Gaussian function In mathematics,is a function of the form: for some real constants a 0, b, c 0, and e ≈ 2.718281828 (Euler’s number).对于一些真正的常量0,b,c 0,和e≈2.718281828(欧拉数)。 Sharpening filter ：锐化滤波器 Smoothing filter/convolution ：smoothing filter are used for blurring and for noise reduction 平滑滤波器用于模糊处理和降低噪声/卷积 Imageenhancement/imagerestoration image Enhancement the process of manipulating an i mage so that the result is more suitable than the original for a specific application. 图像增强处理是对图像进行的加工，使其结果对于特定的应用比原始图像更适合的一种处理。

数字图像处理期末复习题2教学总结

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外文翻译英文

A Distributed Approach for Track Occupancy Detection Abstract This paper investigates the problem of track occupancy detection in distributed settings. Track occupancy detection determines which tracks are occupied in a railway system. For each track, the Neyman–Pearson structure is applied to reach the local decision. Globally, it is a multiple hypotheses testing problem. The Bayesian approach is employed to minimize the probability of the global decision error. Based on the prior probabilities of multiple hypotheses and the approximation of the prior probabilities of multiple hypotheses and the approximationofthereceiving operation characteristic curve of the local detector, a person-by-person optimization method is implemented to obtain the fusion rule and the local strategies off line. The results are illustrated through an example constructed from in situ devices. Key Words:Track occupancy detection,Neyman–Pearson, Generalized likelihood ratio test, Bayesian approach,Distributed detection 1Introduction With respect to the majority of railway systems in China, a quasi-moving block method is employed to specify the safe zone of a train. A key piece of knowledge to be determined is the set of track segments that are occupied, i.e., track occupancy detection. Then the speed restriction curves for the following trains are calculated accordingly. When there are misdetections, collisions may happen; additionally, false alarms may lead to declines of line capacity. Track occupancy detection is achieved by a set of track circuits. The track circuit is a crucial device mainly composed of a transmitter–receiver pair and a track segment. The measurement is the receiving signal at the end of the track. For each segment, a decision is made locally and individually, which leads to frequent ambiguities on which tracks are occupied for the whole line. It means that the false alarm rate of the line increases greatly. Besides, for the next generation of railway systems, a moving block method is adopted. Such a method requires the exact position and velocity of the train. However, those data are not provided in the current detection mechanism.

数字图像处理英文原版及翻译

Digital Image Processing and Edge Detection Digital Image Processing Interest in digital image processing methods stems from two principal application areas: improvement of pictorial information for human interpretation; and processing of image data for storage, transmission, and representation for autonomous machine perception. An image may be defined as a two-dimensional function, f(x, y), where x and y are spatial (plane) coordinates, and the amplitude of f at any pair of coordinates (x, y) is called the intensity or gray level of the image at that point. When x, y, and the amplitude values of f are all finite, discrete quantities, we call the image a digital image. The field of digital image processing refers to processing digital images by means of a digital computer. Note that a digital image is composed of a finite number of elements, each of which has a particular location and value. These elements are referred to as picture elements, image elements, pixels, and pixels. Pixel is the term most widely used to denote the elements of a digital image. Vision is the most advanced of our senses, so it is not surprising that images play the single most important role in human perception. However, unlike humans, who are limited to the visual band of the electromagnetic (EM) spec- trum, imaging machines cover almost the entire EM spectrum, ranging from gamma to radio waves. They can operate on images generated by sources that humans are not accustomed to associating with images. These include ultra- sound, electron microscopy, and computer-generated images. Thus, digital image processing encompasses a wide and varied field of applications. There is no general agreement among authors regarding where image processing stops and other related areas, such as image analysis and computer vi- sion, start. Sometimes a distinction is made by defining image processing as a discipline in which both the input and output of a process are images. We believe this to be a limiting and somewhat artificial boundary. For example, under this definition, even the trivial task of computing the average intensity of an image (which yields a

机械图纸中英文翻译汇总

近几年，我厂和英国、西班牙的几个公司有业务往来，外商传真发来的图纸都是英文标注，平时阅看有一定的困难。下面把我们积累的几点看英文图纸的经验与同行们交流。 1标题栏 英文工程图纸的右下边是标题栏（相当于我们的标题栏和部分技术要求），其中有图纸名称（TILE）、设计者（DRAWN）、审查者（CHECKED）、材料（MATERIAL）、日期（DATE）、比例（SCALE）、热处理（HEAT TREATMENT）和其它一些要求，如： 1)TOLERANCES UNLESS OTHERWISE SPECIFIAL 未注公差。 2)DIMS IN mm UNLESS STATED 如不做特殊要求以毫米为单位。 3)ANGULAR TOLERANCE±1°角度公差±1°。 4)DIMS TOLERANCE±0.1未注尺寸公差±0.1。 5)SURFACE FINISH 3.2 UNLESS STATED未注粗糙度3.2。 2常见尺寸的标注及要求 2.1孔（HOLE）如： （1）毛坯孔：3"DIAO+1CORE 芯子3"0+1; （2）加工孔：1"DIA1"; （3）锪孔：锪孔(注C＇BORE=COUNTER BORE锪底面孔); （4）铰孔：1"/4 DIA REAM铰孔1"/4; （5）螺纹孔的标注一般要表示出螺纹的直径，每英寸牙数（螺矩）、螺纹种类、精度等级、钻深、攻深，方向等。如： 例1.6 HOLES EQUI-SPACED ON 5"DIA (6孔均布在5圆周上（EQUI-SPACED=EQUALLY SPACED均布） DRILL 1"DIATHRO＇ 钻1"通孔（THRO＇=THROUGH通） C/SINK22×6DEEP 沉孔22×6 例2.TAP7"/8-14UNF-3BTHRO＇ 攻统一标准细牙螺纹，每英寸14牙，精度等级3B级 （注UNF=UNIFIED FINE THREAD美国标准细牙螺纹） 1"DRILL 1"/4-20 UNC-3 THD7"/8 DEEP 4HOLES NOT BREAK THRO钻 1"孔，攻1"/4美国粗牙螺纹，每英寸20牙，攻深7"/8,4孔不准钻通（UNC=UCIFIED COARSE THREAD 美国标准粗牙螺纹）

外文翻译(英文)

Title: Modelling of transport costs and logistics for on-farm milk segregation in New Zealand dairying Material Source: Computers and Electronics in Agriculture Author: A. E. Dooley, Parker, H. T. Blair Abstract On-farm milk segregation to keep milk with high value properties separate from bulk milk will affect transport logistics. Separate milk collection, either as independent runs for different milk types,or storage of distinct milk types in the truck and trailer units, may increase the length and number of runs required. Two contrasting regions,with different farm sizes and roading networks were modelled,at two stages of lactation over 20 years. Thirty farms in each region were modelled with 0, 25, 50 and 100% of farms per region changing milk types over a transition period of up to 18 years. Genetic algorithm software was used to search for the order of the farm milk collection pick-ups which gave an optimal, least cost solution for milk collection for each prescribed set of inputs. Milk collection costs within scenario were variable over time depending on the amounts of the different milk types, increasing whenever another run was required, then decreasing over time as the milk load increased. Milk collection cost is small relative to milk income, with the status quo (SQ) cost for milk collection being less than NZ$9.61/kl for the North Island and NZ$13.53/kl for the South Island farm sets. The increased transport costs associated with collecting two milk types ranged from 4.5 to 22.0% more for the different scenarios. The extra cost to an average size North Island farm changing systems (25% farms changing), compared to an equivalent status quo farm, would be between NZ$307 and NZ$1244 per year. Fewer farms changing to differentiated milk production increased the costs per kilolitre of differentiated milk. Keywords: Milk transport; Scheduling; Milk segregation; Collection costs 1.Introduction

南昌大学数字图像处理(双语第三版)课后答案第八章

数字图形处理第八章课后偶数题号作业 8.2 (a)一个单一的原始数据包含2n 位。而最大的长度为2n ，因此需要n 位来表示。每一个行的起始坐标还需要n 位，并且它可以随意的设置在2n 的像素位置。 由21n n =和)1(2)(22N N n avg avg n n n n + =++ =得知： 1) 1(22 2 1>+ = = N n n avg n n C ，即得：12 1 -< -n n avg N (b)当10=n 时，2.5010 10 110 2 2 9 1 10=-= -< -N avg 8.4 根据灰度级数据｛12，12，13，13，10，13，57，54｝可得这条线经过精度为6比特的均匀量化可得他的IGS 编码。具体如下所示： 例如108=01101100，而其中0110为6，可得IGS 量化编码值为-12。同理，根据灰度级数据可得相应的量化误差为｛-12，-11，-7，-4，-12，-13，-8，-3｝所以得到： 84 .7)492(8 1)96416916164925144(8 1== +++++++= e rms 相应信噪比计算如下： 353 492 96 64160176240 12814496 2 2222 2 22 =+++++ ++= SNR rms 8.6 因为x a x b b a log log log 1 = 得知，一个哈特利(Hartley)等于3.322 bits 。通常 信息以e 为底的单元通常称为一个奈特(nat)，从而一个奈特等于1.4427 bits 。 8.8 有两种代码可知：0，11，10和1，00，01。而这些代码相互补充。是根据霍夫曼编码规则得以计算的。 8.10 由题意可得，为a a a a a a a a a 422252663

图像处理英文翻译

数字图像处理英文翻译 （Matlab帮助信息简介） xxxxxxxxx xxx Introduction MATLAB is a high-level technical computing language and interactive environment for algorithm development, data visualization, data analysis, and numeric computation. Using the MATLAB product, you can solve technical computing problems faster than with traditional programming languages, such as C, C++, and Fortran. You can use MATLAB in a wide range of applications, including signal and image processing, communications, control design, test and measurement, financial modeling and analysis, and computational biology. Add-on toolboxes (collections of special-purpose MATLAB functions, available separately) extend the MATLAB environment to solve particular classes of problems in these application areas. The MATLAB system consists of these main parts: Desktop Tools and Development Environment This part of MATLAB is the set of tools and facilities that help you use and become more productive with MATLAB functions and files. Many of these tools are graphical user interfaces. It includes: the

机械外文翻译中英文

英文资料 Limits and Tolerances The breakage of the machine spare parts ,generally always from the surface layer beginning of .The function of the product ,particularly its credibility and durable ,be decided by the quantity of spare parts surface layer to a large extent. Purpose that studies the machine to process the surface quantity be for control the machine process medium various craft factor to process the surface quantity influence of regulation, in order to make use of these regulations to control to process the process, end attain to improve the surface quantity, the exaltation product use the function of purpose . The machine processes the surface quantity to use the influence of the function to the machine (A) The surface quantity to bear to whet the sexual influence 1.Rough degree of surface to bear to whet the sexual influence A just process vice-of two contact surfaces of good friction, the first stage is rough only in the surface of the peak department contact ,the actual contact area is much smaller than theoretical contact area, in contact with each other the peak of the units have very great stress, to produce actual contact with the surface area of plastic deformation, deformation and peak between the Department of shear failure, causing serious wear. Parts wear may generally be divided into three stages, the initial stage of wear and tear, normal wear and tear all of a sudden intense phase of stage wear. Parts of the surface roughness of the surface wear big impact. In general the smaller the value of surface roughness, wear better. However, surface roughness value is too small, lubricants difficult to store, contact between the adhesive-prone elements, wear it to increase. Therefore, the surface roughness of a best value, the value and parts of the work related to increased work load, the initial wear increased, the best rough surface is also increased. 2.Cold Working hardening the surface of the wear resistance Processing the Cold Work hardening the surface of the friction surface layer of metal microhardness increase, it will generally improve the wear resistance. Cold Working but not a higher degree of hardening, wear resistance for the better, because too much will lead to hardening of the Cold Working excessive loose organization of