欧姆龙Fins通讯手册

VC++之MFC类库中文手册（含MFC控件使用手册），很好的一套资料，里边另配一个txt的说明

该代码利用python（numpy）生成ply文件，并将三维点云数据写入ply文件。生成的ply文件可以直接用meshlab打开查看点云。这个积分太高了，我重新上传了一份，链接：https://download.csdn.net/download/weixin_41457494/11438608

稀疏阵的方向图仿真，给出了不同条件下的稀疏阵列的方向图

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

安信可ESP-12S WIFI文档，安信可利用ESP8266芯片封装的12S模块，可以快速连接WIFI路由器，从而实现物联网！！ESP-12S规格书目录1.产品概述21.1.特点…………1.2.主要参数…垂·2.接口定义……3.外型与尺寸4.功能描述……84.1. MCU84.2.存储描述84.3.晶振,,,,,,+·++444.接口说明……4.5.最大额定值…104.6.建议工作环境114.7.数字端口特征…115.RF参数………………116.功耗127.倾斜升温…………………………………………138.原理图…………9.产品试用…16深圳市安信可科技有限公司http://www.ai-thinker.comESP-12S规格书1.产品概述ESP-12SwiFⅰ模块是由安信可科技开发的,该模块核心处理器εSP8266在较小尺寸封装中集成了业界领先的 Tensilica l106超低功耗32位微型MCU,带有16位精简模式,主频支持80MHz和160MHz,支持RTOS,集成Wi- FI MAC/BB/RF/ PA/LNA,板载天线。该模块攴持标准的IE802.11b/g/n协议,完整的τpP协议栈。用户可以使用该模块为现有的设备添加联网功能,也可以构建独立的网络控制器ESP8266是高性能无线SOC,以最低成本提供最大实用性,为WⅰFi功能嵌入其他系统提供无限可能。射频MAC接口接收②模拟接收寄存器SDIO门7SPI射频CPU内核发射模拟发射成帧器GPIO锁相环Hvco)12|锁相环加速器12C电源管理晶振偏置电路SRAM电源管理图1ESP8266EX结构图ESP8266EX是—个完整且自成体系的WFi网络解决方案,能够独立运行,也可以作为从机搭载于其他主机McU运行。ESP8266EⅩ在搭载应用并作为设备中唯一的应用处理器时,能够直接从外接闪存中启动。内置的髙速缓冲存储器有利于提高系统性能,并减少內存需求。另外—种情况是,ESP8266EⅩ负责无线上网接入承担WⅰFi适配器的任务时,可以将其添加到任何基于微控制器的设计中,连接简单易行,只需通过SPI/SDIO接口或I2C儿UART口即可。ESP8266EX强大的片上处理和存储能力,使其可通过GPIO口集成传感器及其他应用的特定设备,实现了最低前期的开发和运行中最少地占用系统资源。ESP8266EⅩ高度片內集成,包括天线开关 balun、电源管理转换器,因此仅需极少的外部电路,且包括前端模组在内的整个解决方案在设计时将所占PCB空间降到最低。深圳市安信可科技有限公司http://www.ai-thinker.comESP-12S规格书有ESP8266EX的系统表现出来的领先特征有∵节能在睡眠/唤醒模式之间的快速切换、配合低功率操作的自适应无线电偏置、前端信号的处理功能、故障排除和无线电系统共存特性为消除蜂窝/蓝牙/DDR/VDS/LCD干扰11.特点80211b/g/n·内置 Tensilica L106超低功耗32位微型McU,主频攴持80MHz和160MHz,支持RTOS·内置10bit高精度ADC内置TCPP协议栈内置TR开关、 balun、LNA、功率放大器和匹配网络内置PLL、稳压器和电源管理组件,802.11b模式下+20dBm的输出功率A-MPDU、A-MSDU的聚合和045的保护间隔WⅰFi@24GHz,支持WPA∧NPA2安全模式支持AT远程升级及云端OTA升级支持 STA/AP/STA+AP工作模式支持 Smart Config功能(包括 Android和ioS设备)HSPI、UART、I2C、I2S、 IR Remote control、PWM、GPIO深度睡眠保持电流为10uA,关断电流小于5uA2ms之内唤醒、连接并传递数据包·待机状态消耗功率小于1.0mW(DTM3)工作温度范围:-40°℃-125°C深圳市安信可科技有限公司http://www.ai-thinker.comESP-12S规格书12.主要参数表1介绍了该模组的主要参数。表1参数表类别参数说明标准认证FCC/CE/TELEC无线参数无线标准80211b/g/n频率范围24GHz-25GHz(2400M-24835M)UART/HSPI/I2C/12S/Ir Remote Contorl数据接口GPIO/PWM工作电压30~3.6V(建议33V)工作电流平均值:80mA硬件参数工作温度40°~125存储温度常温封装大小16mm x 24mm * 3mm外部接口N/A无线网络模式station/softAP/SoftAP+station安全机制WPA/PA2加密类型WEP/TKIP/AES升级固件本地串口烧录/云端升级/主机下载烧录软件参数支持客户自定义服务器软件开发提供SDK给客户二次开发网络协议Ipv4, Tcp/udp/Http/ftP用户配置AT+指令集,云端服务器 Android/ iOS APP深圳市安信可科技有限公司http://www.ai-thinker.com4ESP-12S规格书2.接口定义ESP-12S共接出16个接口,表2是接口定义。图2ESP-12S管脚图RST ID16 TXDBADC 2 aDI5 RXD8EN 314工05工015+p13041014512I0B工01261102I013710I015. 9GND表2ESP-12S管脚功能定义序号in脚名称功能说明1RST复位模组2ADOA/D转换结果。输入电压范围0~1V,取值范围:0~1024EN芯片使能端,高电平有效4IO16GPo16;接到RST管脚时可做 deep sleep的唤酲。IO14GPIO14 HSPI CLK6IO12GPIO12: HSPI MISOIO13GPIO13: HSPI MOSI UARTO CTSVCO33V供电GNDGND10IO15GPIo15: MTDO: HSPICS: UARTO RTS深圳市安信可科技有限公司http://www.ai-thinker.com5ESP-12S规格书102GPIO2 UART1 TXD12100GPIOO13IO4GPIO414IO5GPIO515RXDUARTO RXD: GPIO3TXDUARTO TXD: GPIO1表3引脚模式模式GPIO15GPIOOGPIO2UART下载模式低Flash boot模式低低高高高表4接收灵敏度参数最小小值典型值最大值单位输入频率24122484MHZ输入电阻50输入反射-10dB722Mbps下,PA的输出功率141516d Bm11b模式下,PA的输出功率17.518.5195d Bm灵敏度DSSS,1 Mbps-98d BmCCK, 11 Mbps-91d Bm6 Mbps(1/2 BPSk)93d bm深圳市安信可科技有限公司http://www.ai-thinker.comESP-12S规格书54 Mbps(3/4 64-QAM)dBHT20, MCS7(65 Mbps, 72.2 Mbps)d Bm邻频抑制OFDM, 6 Mbps37dBOFDM, 54 Mbpsd BHT20 MCSO37d BHT20, MCS7203.外型与尺寸ESP-12S贴片式模组的外观尺寸为24mm*16mm*3mm(如图3所示)该模组采用的是容量为4MB,封装为SOP-210mil的 SPI Flash。模组使用的是3DBi的PCB板载天线。CeaESP-12scE0890FCC ID:2AHMR-ESP12SSMLAG 802-图3ESP-12S模组外观深圳市安信可科技有限公司http://www.ai-thinker.comESP-12S规格书16m16mm图4ESP-12S模组尺寸平面图表5ESP-12S模组尺寸对照表长宽PAD尺寸(底部)Pin脚间距24 mm16 mm3 mm1 mm x 1.2 mm 2 mm4.功能描述41. MCUESP8266EX内置τ ensilica l106超低功耗32位微型McU,带有16位精简模式,主频攴持80MHz和160MHz,支持RTOS。目前WiFi协议栈只用了20%的MIPS,其他的都可以用来做应用开发。McU可通过以下接口和芯片其他部分协同工作:1连接存储控制器、也可以用来访问外接闪存的编码RAM/ROM接口(BuS)2冋同样连接存储控制器的数据RAM接口(dBus)3访问寄存器的AHB接口4.2.存储描述421.内置SRAM与RoMESP826EX芯片自身內置了存储控制器,包含ROM和SRAM。MCU可以通过iBus、dBus和AHB接口访问存储控制器。这些接口都可以访问R○M或RAM单元,存储仲裁器以到达顺序确定运行顺序。基于目前我司 DemO sdK的使用SRAM情况,用户可用剩余SRAM空间为: RAM size

【实例简介】樊昌信《通信原理》研究生考试考点精讲，2020年全国研究生招生考试海文考研专业课辅导教材（南京邮电大学）

本文主要对医学超声图像三维可视化进行研究。以肝脏二维超声图像为例进行三维重建。

国内进行水文分析较好的工具，由于软件大小超过要求，需要三个安装包同时下载解压即可安装，成为gis的插件

标准的深度优先搜索算法，可实现节点遍历、产生随机路由、检测图中是否有回路等功能，-Standard depth-first search algorithm, the node traversal can be achieved, resulting in a random routing, testing whether there is any loop diagram functions

针对基本粒子群优化(basic particle swarm optimization,简称bPSO)算法容易陷入局部极值、进化后期的收敛速度慢和精度低等缺点,采用简化粒子群优化方程和添加极值扰动算子两种策略加以改进,提出了简化粒子群优化(simple particle swarm optimization,简称sPSO)算法、带极值扰动粒子群优化(extremum disturbedparticle swarm optimization,简称tPSO)算法和基于二者的带极值扰动的简化粒子群优化(extremum disturbed andsimple particle swarm o