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各种常见的窗函数，以及它们的时域图，非常清晰，

时域有限差分学习书籍，有研究FDTD方法的可以学习学习国防科技图书出版基金第二届评审委员会组成人员名誉主任委员怀国模主任委员黄宁副主任娄员殷鹤龄高景德陈芳允曾铎员尤子平朱森无朵英贤按姓氏笔划为序)刘仁何庆芝何因伟何新贵宋家树张汝果范学虹胡万忱柯有安侯迁候正明莫梧生崔尔东秘书长刘琯德时域有限差分法(Fnte- Differerce Time-Domain Method简称FDTD Method)是求解电磁问题的种数值技术,它是在1966年由K.S.Yee第一次提出的。fDTD法直接将有限差分式代替麦克斯韦时域场旋度方程中的微分式,得到关子场分量的有限差分式,用具有相同电参量的空间网格去模拟被研究体,选取合适的场初始值和计算室间的边界条件,可以得到包括时间变量的麦克斯韦方程的四维数值解。通过傅里叶变换可求得三维空间的频域解20多年来FDTD法历经了一个蓬勃发展的过程。最初是用它来求解金属体上的散射问题,用的是笛卡尔坐标系,使空间单元网格呈直角六面体。鉴于当时的计算机容量水平,特别是FDTD技术本身尚有若重要问题未很好解决,使得早期的数值精度不够高,应用范围也不很广,这种局面大约延续到70年代末期。随着FDTD技术的发展,首先需要解决的是有限计算空间的无反射截断问题,早期采用的一种方法是加大边界与散射体间距离,以在边界上构成外向行波,这种方法精度不高、计算空问亦大。直到将波方程的二阶近似用以处理边界上的场值,得到了较好近似的吸收边界条件,才将这个间题的解决向前推进了一大步在直角坐标系中用FDTD技术进行模拟时,光滑曲线形媒质表面将呈锯齿形状这可能产生沿面的表面波,加大了数值色散误差,解决这个问题的有效方法是“共形”技术的提出,这包括:或是使用曲线坐标系使媒质表面与坐标曲线共形,或是在直角坐标系中改变媒质介面上的网格形状,使二者共形,利用共形网格明显提高了计算精度。在类电磁问题中,当媒质结构尺寸比网格尺寸小时(如细线、窄槽或薄介质层等),将使FDTD模拟变得很困难。近来相继出现以麦克斯韦方程的国路积分形式建立相应FDTD算法式,FDTD与其他方法(如积分方程法或矩量法)的混合技术,以及媒质参数竹网格平均技术等,均提供了解决这类特殊问题的途径。FDTD法的特点是很易得到被研究体的近场,但不易一次直接得到远场值。80年代初期提出的利用等效原理将频城近场变换为远场是解决这个问题的好方法,近几年又将此技术发展到时域这二种路径给求解散射间题和天线问题提供了强有力的工具。值得提出的是,早期fTD方法中没有计及媒质的色散特性,即假定被研究媒质的电参数是与频率无关的。实际上自然界中有很多媒质的电参数具有很强的色散特性,近几年已开始注意研究色散媒质中的FDTD算法,为解决这电磁领域内难题铺平了道路。上述几方面问题的进展有力推动了FDTD技术的发展和应用,使它在解决复杂形体结构和多种媒质并存的一类呵题中占有重要的一席之地。今天,它不仅在电磁散射、电磁兼容预测、生物电磁学中得到卓有成效的应用,而且在天线做波技术、光电子学等的应用中意益受到重视。本书内容包括三部分:第一部分论述了FDTD法基本知识和各种FDTD算法,包括各种坐标系和特殊结构媒质的算法,以及FDTD与其他方法相结合的混合法等;第二部分介绍了FDTD法在电磁学各领域中的应用情况,内容涉及电磁散射微波传输线、天线、电磁榘容预測及生物电磁学范畴;第三部分讨论近期发展的色散媒质的FDTD算祛原理及其应用情况。本书在给出各种应用实例时,多将FDID法数据与理论值或实验数据或其他数值解数据(如矩量法等)进行比较。除早期发表的少数例子误差稍大外,大多数均与相比较的数据吻合很好。从目前水平看,在分析…般散射问题中,数值误差约在L%~3%附近(RCS的误差略大些),而在求谐振器本征值问题中,FDTD数值解与理论值误差低于百分之,某些情况能小于千分之一,这个精度是很喜人的。可以无夸张地说,FDTD法与其他数值解从精度上讲是可以媲美的,有的则有胜过。加之FDTD法得到的是时域解,通过傅氏变换可得到频域解。即它具有次时域计算代替频域上逐点计算的潜力。这些均L表示FDTD法具有较明显的优势。本书是作者尝试将已发表在不同场合不同时间的有关资料经整理推演、加工编写成专著。内容取材上亦包括作者及同事们近几年在这方面开展的工作结果。编写本书的目的是希望能起到抛砖引玉的效果。希给初学者提供…个入门途径,给从事这方面工作的同行们提供较系统的参考资料,以便更好地促进FDTD技术的发展和更进一步拓宽它的应用。由于作者才疏学浅,加上时间关系,错误和不足在所难免,上述目的恣难如愿敬请各位专家学者和读者多提供宝贵意见。在本书确立大纲的过程中,得到北京理工大学张德齐教授和楼仁海教授、西安交通大学汪文秉教授的帮助,汪文秉教授对内容安排提出了贵意见。要特别提到的是,在本书编写过程中得到中国科学技术大学旅美陈金元博士的大力支持和帮助陈博士及时寄来最新研究资料(见§7.6以充实本书内容。书稿完稿后,张德齐教授通阅了全稿,并提出宝贵意见国防工业出版社在本书出版过程中给予很多帮助,作者在此对他们表示衷心的感谢作者t993年8月于北京内容简介本书重点介绍」时域有限差分(FDTD)法的基本知识及其在电磁学各个领域内的应用。全书包括二部分(共八章),第一部分论述了FDTD法的基本知识(第…章)和各种FDTD算法,包括各种坐标和特殊结构媒质中FDTD算法及混合算法等(第二章);第二部分介绍FDTD法的爷种应用,内容涉及电磁散射(第三章〉微波传输线和谐振腔(第四章)、天线(第五章)、电磁兼容预测第六章)生物电磁学(第七章)等领域;第三部分介绍近期发展的色散媒质屮FDTD算法原及其应用情祝等(第八章〕。木书可供从事时域计算电磁学理论和应用妍究的人员参考,亦可供有关专业教师、研究生及商年级大学生作选修和参考用书目·录第一章时域有根差分法基本知识1.1支克斯韦方程1)].2FTD基本方程■h吾早4中■暑h音h鲁↓ψ中4山■■骨日◆p4白(生)1.3解的稳定性“……““〔l1)1.4边界条件…(13)1.5激励派的类型和设置……………………………(22)816误差分析………*………(29)§1.7近场一远场变换山中■冒↓d4白■■■e40)氵1.8FDTD数值解步骤…………(45〕参考文献■··■跏■·幽自嚞ψ■■·自·■甲血幽b中■●鲁歌●■甲晉『甲●■目■■46第二章FDTD算法变异48)82.1一般曲线坐标系的FDTD算法4甲●鲁ψψ■“ψ晕P山血曾■■■省口_P■口(48)§2.2正交曲线坐标系的PDTD算法(58}2.3非均匀网格尺寸的FDTD算法…(69)2.4细薄结构媒质的FTD算法……………*………(80)2.5FDTD瞬态积分方程的混合算法:(95§2.6FDTD矩量法时混合算法…………………*………(101)参考文献…………………………………………(105)第三章在电磁散射问题中的应用聊司自■电■■悬■■··ψb■■t最聊10883.1二维散射体■■画■·■唱口■■』烟·■口甲■唱■■即■■■口·吾■昌■■■■即■■■晶』h画p■■■昌〔108§3.2三维敢射体……………(114)3.3RCS计算……〔121)§3.4散射体的时域综合……………………**……(134)参考文献(143)第阿章在徽波传输线和谐振腔中的应用…………………(141徵带和共面传输线咖自b·山山山啬■■山■■ψ·;跏·■■“■士鲁■b■口■■■动●咖【41§4.2徼带不均匀性和徼带元件●日日鲁■日聊聊昏目申聊■与;自语↓ψ■ψ口一·↓c自ψb53)氵4.3波导传贛线元件……………………………………(63)8.4谐振腔的本征值……4…(j72)4.5谐振腔的e值(I名1参考文献…………………………………………(185第五章在天线问题中的应用·……(!8?)§5.1圆柱形单极天线………4■·↓■自·h■■■■■■■■甲4■■■▲187)5.2波导口和喇明线………………………………………(196)§5.3徽带贻片天线200)§5.4天线互朝的计算…ra……(210)参考文献1■幽昏p■■◆(215第六章在电磁兼容预测中的应用…(218§6·]瞬变电驚环境下飞机表面效应………“(216)§6.2EMP对连接有尾气焰导弹体的效应…(22)s63EM场透入导弹导引头的预浏■■■非十(230)6.4飞行体上微带贴片天线的EMP效应……a(233)6.5TEM传导胞腔中不均匀性影响的预测…-4…*4(239参考文献昏■■·聊■●■■■·ψ■山幽■如卓■■ψ卩■■中斷鲁晋■■口自■■导画晋■b山1〔241第七章在生物电磁学中的应用……246§7.1生物组织的电磁特性及人体电磁模型……………"……(246)72平面波照射下人体内的电磁效应号昌◆+卓b4即u(z56)7.3工业加热器对人体的作用…………………………(263)7.4动力电的人体效应…sa…(2687.5高压EMP的生物效.…·…(273)N7.6虾篾电话的人体效应…■■■■■↓鲁号↓個山山……(280)参考文………………………………………(2865第八章色教媒质的FDTD算法日■■d十■T■一一會■■『■■■血288)N8.1离散时域卷积建立FDTD方程……〔288N8.2由德拜方程和频域场到吋域的直接变换建立FDTD方程"sr…:…(295)氵8.3由z变换建立FDTD方程日ψ号■自卓自甲ψ吾■■■日■■■道语晶画『4b即44■(298)4色散媒质的吸收边界条件…………………"………(303)8.5(FD)TD法应用举例……(3058.6表面阻抗概念在fDTD法中的应用……(314)s8.了表面阻抗FDT法应用举例………■·■■b■324)参考文献(召30

无刷直流电机全桥驱动电路，原理图+PCB，PCB带3D视图，方便直观查看PCB。此驱动板可同时独立的驱动两路无刷直流电机。

Android Studio 网格状表示的室内定位APP，采用三边定位法，适合做毕业设计（手动滑稽）。

比较完善的ISODATA聚类分析。支持手动选择初始聚类中心，类似监督法分类。支持8位、24位BMP图像操作。选用2种ISODATA聚类算法。聚类结束后可手动修改类别颜色。

MVDR 算法及相关文献 非常详细算法的matlab程序

通过opencv对图片上的数字进行识别。识别方式和步骤主要是寻找出数字的外轮廓，然后根据轮廓外接矩阵对数字进行分割，然后根据模板，求出其与分割好的数字的像素差值，找出最匹配的数字。

Rohde&Schwarz 频谱仪操作手册（英文） 1145.5850系列全英文，详细的操作方式，各类使用技巧R&S FSHContentsContentsSpecificationsSafety InstructionsCertificate of qualitEC-Certificate of conformitySupport Center AddressList of R&S RepresentativesPutting into OperationFront view1.1Putting into Operation1.2Unpacking the Instrument1.2Setting up the InstrumentSwitching on the Spectrum Analyzer1.4Spectrum Analyzer Connectors1.5Screen SettingsQCountry-Specific Settings1.10Setting the Date and TimeSetting the date.1.11Setting the time1.1Charging the Battery......1.12Selecting the Instrument Default Setup1.13External Reference /External Trigger Switchover1.14Controlling the rF Attenuator1.15Using a Preamplifier…1.15PIN Entr1.17Connecting Printers.1.19Setting the Baud rate for Remote Control1.21Enabling Options1.21Checking the Installed options1.221145.5973.12E-15ContentsR&S FSH2 Getting Started2.Measurements on cw signals2.1Level measurement2Setting the Reference Level量‘面2.2Frequency Measurements2.3Harmonic Measurements of a sinewave Signal面面2.4Power Measurements Using the Power Sensor2.5Power and return loss measurements with the r&s FsH-z14 or the r&s FSH-Z444427Two-Port Transmission measurements2.9Measurement of return loss2.11Performing Distance-To-Fault Measurements...2.14Operation in Receiver Mode2.20Measuring the carrier-to-Noise power ratio2.Determining the Reference2.26Sts…2.26Selecting the reference channel2.27Entering the channel bandwidth of the reference channel2.27Selecting the unit for the reference...2.27Manually entering the reference2.27Automatic level adjustment2.27Measuring the Noise Power and Calculating Carrier Power /Noise Power.........2.28Selecting the result display2.28Frequency setting of the noise channel..2.28Setting the noise channel measurement bandwidth2.29Setting the C/N channel bandwidth2.29Automatic level adjustment2.29Correcting the displayed average noise level2.30Hiding the result display2.30Saving and Recalling Settings and Test Results2.31Saving Measurement Results2.31Saving Calibration Data2.32Recalling measurement results2.33Printing Out Measurement Results……2.341145.5973.122E-15R&S FSHContents3 Operation3.Screen LayoutScreen layout for spectrum-mode measurements without markers3.1Screen layout when the marker mode is selected3.2Entering Measurement ParametersEntering values and texts3.3Entering units3.4Menu overview.3.5Frequency entryFrequency span...Level setting…3.5Bandwidth settingTrace setting3.6Measurement functions3.7Marke3.10Save and print menu3.12Instrument setup3.12Status display3.12Menus in the Receiver Mode(option R&S FSH-K3)3.13Menu for 3GPP BTS Code domain Power Measurement (Option R&S FSH-K4)3.16Menu for Vector Voltmeter(Option R&S FSH-K2)3.161145.5973.12E-15ContentsR&S FSH4 Instrument functions4Instrument Default Setup4.1Status Display..................4.1Setting the Frequency4.2Entering the center frequency..4.2Setting a frequency offset4.2Entering the center-frequency step size4.3Entering the start and stop frequency4.4Working with channel tablesSetting the Span1面4.6Setting the Amplitude Parameters4.7Setting the reference levelEntering the display range94.9Entering the display unit4.9Entering the reference offset4.10Entering the input impedance.…………4.10Setting the Bandwidths4.11Resolution bandwidth4.11Video bandwidth4.13Setting the Sweep4.14Sweep time.4.15Sweep mode.4.15Trigger4.16Trace Settings4.19Trace mode∴4.19Detector4.20Trace memory…4.22Trace mathematics4.23Using the Markers4.24Automatic marker positioning .......4.25Using more than one marker at a time(multimarker mode).........,4.27Marker functions4.30Measuring the noise power density4.30Measuring the frequency4.31Measuring the filter bandwidth or the signal bandwidth4.32aF demodulation4.331145.5973.12E-15R&S FSHContentsUsing the dis play line…….….….….….….….….….…..….….……….…..34Setting and Using the Measurement Functions4.35Measuring the channel power of continuously modulated signals………………4.35Selecting the standard4.36Setting the reference level4.38Setting the channel bandwidth4.38Changing the spaPower displaPower measurements on TDMA signals4.42Selecting a standard∴4.42Setting the measurement time4.44Optimizing the reference level ..4.44Power readout4.45Setting the trigger4.45Measuring the occupied bandwidth4.46Selecting a standard4.47Setting the reference level4.48Setting the channel bandwidth4.49Entering the power percent to determine the occupied bandwidth4.50Displaying thupied bandwidth4.50Changing the spai1145.5973.12E-15ContentsR&S FSHMeasuring the Carrier-to-Noise Ratio.......4.52Determining the reference4.53Setting the reference channel4.53Setting the reference channel bandwidth……4.53Setting the analyzer reference level for the reference channel measurement4.54Manual reference mode4.54Inserting the c/N referenceUnits of the c/n reference4.55StandardsUSER Standard4.56User-specific standards4.56Predefined user-specific standards4.59Predefined user-specific standard Digital TX4.59Predefined user-specific standard ANalog tv mode4.60Predefined user-specific standard ctx4.60Measuring the noise channel power and calculating the carrier power/noise power.4.62Frequency setting of the noise channel………4.63Setting the noise channel bandwidth4.64Setting the C/N ratio channel bandwidth4.64Setting the reference level during noise channel measurement.4.65Selecting the c/ N result display..…,…4.65C/N measurement result display4.66Changing the span4.66Correction of inherent noise power4.67Using the R&S FSH in receiver mode4.68Setting the frequencySetting the reference level,,,。.。4.71Setting the bandwidth4.72Setting the detector4.73Setting the measurement time4.73Measurement on multiple frequencies or channels(scan)4.74Measurements using the power sensor4.76Connecting the power sensor……4.76Zeroing the power sensor.4.78Selecting the unit for the power readout4.79Setting the averaging time.……4.80Taking additional loss or gain into account4.81Measuring forward and reflected power∴4.82Zeroing the power sensor4.84Setting the power measurement weighting4.85Selecting the unit for the power readout4.86Taking additional attenuation into account4.881145.5973.126E-15R&S FSHContentsTwo-port measurements with the tracking generator489Measuring the transmission of two-ports4.91Vector transmission measurement494Measuring the transmission magnitude........4.96Measuring the transmission phase4.96Measuring the electrical length when measuring transmission面B国4.99Measuring the group delay when measuring transmission4.100Transmission measurement using the connected VSWR Bridge R&S FSH-Z3.. 4.102Sppectrum measurements with the VsWR Bridge R&s FSH-Z3 or R&S FSH-Z2connectedSetting for detecting the R&S FSH-Z3 in the transm. and spectr. measurement .. 4.104Supplying DC voltage to active DUTs4.105Reflection measurements4.105Scalar measurement of reflection4.106Vector measurement of reflection4.108Measuring the reflection magnitude4.111Measuring the reflection phase.……4.111Measuring the electrical length when measuring reflection4.112Displaying the reflection in the Smith chart4.113Measuring the group delay when measuring reflection4.118Selecting the calibration standards4.120Spectrum measurements with the vswr Bridge r&s FSH-Z3 or R&S FSH-z2connected4.121Settings for detection of the R&SFSH-z2andR&SFSH-Z3………4.122One-Port measurement of cable loss4.123Vector voltmeter.4.124Reflection measurements(S11)4.125Measuring transmission coefficients(S21)4.128Cable measurements4.134Cable selection∴4.135Selecting the frequency range…4.138Calibrating the test setupa.::::::.“14.139Locating cable faults by means of the marker function4.142Measuring spectrum and reflection4.145Further information∴4.146Setting the span4.146Selecting the center frequency.........∴4.147Measurement4.148Length measurement accuracy4.148Using limit Lines∴4.149Measurements with limit lines国面面4.151Definition range of limit lines4.152Data sets containing limit lines...4.1521145.5973.127ContentsR&S FSHMeasuring with Transducer Factors.4.153Unit for measurements with transducers4.156Reference level settings for measurements with transducers4.156Frequency range of transducer………4.156Data sets containing transducer factors4.156Field-Strength Measurement with Isotropic Antenna∴4.157Connecting the antenna to the R&S FSH4.157Measurement of the resultant field strength in a transm. channel with large bandwidth .......4.159Code Domain Power Measurement on 3GPP FDD Signals.4.166Saving and Loading Instrument Settings and Measurement Results4.173Saving results4.174Entering a data set name4.175Loading measurement results.4.175Deleting saved data sets4.176Deleting all data sets4.177Printing out Measurement Results4.178Measurements4.179How a spectrum analyzer operates…4.1791145.5973.12E-15

采用BP神经网络对150组股票交易数据进行拟合，拟合精度较好。