医学图像分析MATLAB代码

如果你从我的这篇博客http://blog.csdn.net/j56754gefge/article/details/40708679里下载了DPM目标检测代码，它所使用的模型文件是保存在txt里的，而MATLAB训练出来的模型是mat文件，该函数提供将MATLAB模型保存为txt文件的m函数。

使用python进行58同城招聘信息进行爬取

采用COMSOL软件，对平面变压器的仿真过程进行叙述，让大家了解平面变压器的仿真流程，是个很好的指导教材Solved with COMSOL Multiphysics 5.0Results and discussionThe magnetostatic analysis yields an inductance of 0. 1l mH and a dc resistance of0. 29 mQ2. Figure 2 shows the magnetic flux density norm and the electric potentialdistributionvolume: Coil potentiaL()Volume: Magnetic flux density norm (t▲0.07▲2.88×10-42.51.50.03050.01V656×107v0igure 2: Magnetic flux density norm and electric potential distribution for themagnetostatic analysisIn the static (DC) limit, the potential drop along the winding is purely resistive andcould in principle be computed separately and before the magnetic flux density iscomputed. When increasing the frequency, inductive effects start to limit the currentand skin effect makes it increasingly difficult to resolve the current distribution in thewinding. At sufficiently high frequency, the current is mainly flowing in a thin layernear the conductor surface. When increasing the frequency further. capacitive effectscome into play and current is flowing across the winding as displacement currentdensity. When going through the resonance frequency, the device goes from behavingas an inductor to become predominantly capacitive. At the self resonance, the resistivelosses peak due to the large internal currents Figure 4 shows the surface current3 MODELING OF A 3D INDUCTORSolved with COMSOL Multiphysics 5.0distribution atl MHz. Typical for high frequency the currents are displaced towardsthe edges of the conductor.freq(1)=1.0000E6_Surfaee: Surface-current density norm (A/)▲18618Q16010￥1.02Figure 3: Surface current density at I MHz (below the resonance frequency)Figure 4 shows how the resistive part of the coil impedance peaks at the resonancefrequency near 6MHz whereas Figure 5 shows how the reactive part of the coiimpedance changes sign and goes from inductive to capacitive when passing throughthe resonance4 MODELING OFA3DINDUCTORSolved with COMSOL Multiphysics 5.0Global: Lumped port impedance(Q2)d port impedance7.5G6.583275655545352510.10.20.30.40.509igure 4: Real part of the electric potential distribution5 MODELING OF A INDUCTORSolved with COMSOL Multiphysics 5.0Global: Lumped port impedance(Q2)35000Lumped port impedance200001000050000500010000-1500020000250000.10.20.30.40.50.60.70.809Figure 5: The reactive part of the coil impedance changes sign hen passing through theresonance frequency, going from inductive to capacitiveModel library path: ACDC_Module/Inductive_ Devices_and_coils/inductor 3dFrom the file menu. choose newNEWI In the new window click model wizardMODEL WIZARDI In the model wizard window click 3D2 In the Select physics tree, select AC/DC> Magnetic Fields(mf)3 Click Add4 Click StudyMODELING OF A3D NDUCTORSolved with COMSOL Multiphysics 5.05 In the Select study tree, select Preset Studies>StationaryGEOMETRYThe main geometry is imported from file. Air domains are typically not part of a CaDgeometry so they usually have to be added later. For convenience three additionaldomains have been defined in the CAd file. These are used to define a narrow feed gapwhere an excitation can be appliedport l(impl)I On the model toolbar, click Import2 In the Settings window for Import, locate the Import section3 Click Browse4 Browse to the models model library folder and double-click the filenductor 3d. mphbinSphere /(sphl)I On the Geometry toolbar, click Sphere2 In the Settings window for Sphere, locate the Size section3 In the Radius text field, type 0.2ick to expand the Layers section. In the table, enter the following settingsLayer nameThickness(m)ayer0.055 Click the Build All Objects buttonForm Union(fin)i On the Geometry toolbar, click Build AllClick the Zoom Extents button on the Graphics toolbar7 MODELING OF A 3D INDUCTORSolved with COMSOL Multiphysics 5.03 Click the Wireframe Rendering button on the Graphics toolbarThe geometry should now look as in the figure below0.1-0.10.20.0.0.1y0.0.2Next, define selections to be used when setting up materials and physics Start bdefining the domain group for the inductor winding and continue by adding otheruseful selectionsDEFINITIONSExplicitI On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type Winding3 Select Domains 7,8 and 14 onlyI On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type Gap3 Select domain 9 onlI On the Definitions toolbar, click Explicit8 MODELING OF A3DINDUCTORSolved with COMSOL Multiphysics 5.02 In the Settings window for Explicit, in the Label text field, type core3 Select Domain 6 onlyExplicit 4I On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type InfiniteElements3 Select Domains 1-4 and 10-13 onlyExplicit 5I On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type Non-conducting3 Select Domains 1-6 and 9-13 onlyI On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type Non-conductingwithout Ie3 Select Domains 5, 6, and 9 only.Infinite Element Domain /(iel)Use infinite elements to emulate an infinite open space surrounding the inductorI On the definitions toolbar click Infinite element domain2 In the Settings window for Infinite Element Domain, locate the Domain Selectionsection3 From the Selection list. choose Infinite Elements4 Locate the Geometry section From the Type list, choose SphericalNext define the material settingsADD MATERIALI On the Model toolbar, click Add Material to open the add Material window2 Go to the Add material window3 In the tree, select AC/DC>Copper.4 Click Add to Component in the window toolbar9 MODELING OF A 3D INDUCTORSolved with COMSOL Multiphysics 5.0MATERIALSCopper(mat/)I In the Model Builder window, under Component I(comp l)>Materials click Copper(matD)2 In the Settings window for Material, locate the Geometric Entity Selection section3 From the Selection list, choose windingADD MATERIALI Go to the Add Material window2 In the tree. select built-In>Air3 Click Add to Component in the window toolbarMATERIALSAir(mat2I In the Model Builder window, under Component I(comp l)>Materials click Air(mat2)2 In the Settings window for Material, locate the Geometric Entity Selection section3 From the Selection list, choose Non-conductingThe core material is not part of the material library so it is entered as a user-definedmateriaMaterial 3(mat3)I In the Model Builder window, right-click Materials and choose Blank Material2 In the Settings window for Material, in the Label text field, type Core3 Locate the geometric Entity Selection section4 From the selection list choose Core5 Locate the Material Contents section. In the table, enter the following settingsPropertName Value Unit Property groupElectrical conductivity sigma0S/IBasicRelative permittivity epsilonrBasicRelative permeability mur1e3Basic6 On the model toolbar. click Add Material to close the Add Material windowMAGNETIC FIELDS (MF)Select Domains 1-8 and 10-14 only0MODELING OF A 3D INDUCTOR

代码亲测可用，直接调用stoi函数，格式是stoi(x,y,fs)，分别是干净语音，带噪语音，采样频率

【实例简介】这是本人在使用uniapp开发APP或者微信小程序时的框架，包含个人中心和启动页广告，以及登录等界面。开发者直接使用此框架，在此基础上开发自己的内容。后台网址也写了一些，大家可以更换自己服务器网址，我本人后台是用php写的。分享给大家~

标准Modbus TCP通信测试工具，两个测试工具主要用于plcModbus TCP通信测试，可分别可是客户端和服务器端测试环境:西门子SMART s7-200 PLC

在matlab中用RF的方法对IRIS数据进行分类，取一百个数据用于训练，五十个数据用于测试，并统计错误率，代码经本人运行，可用于学习随机森林

整理最全AD20原理图库文件：包含最基本元件，各类电阻、电容、电感、二极管、三极管、场效应管、数码管、按键、以太网、传感芯片、继电器、wifi、32芯片、51芯片等

车载充电机（OBC）是新能源汽车必不可少的核心零部件，其市场规模随着新能源 汽车市场的快速增长而扩大。据相关数据分析，2016 年，电动汽车车载充电机市 场规模约 20 亿元，未来几年随着新能源汽车产量的逐年提升，预计到 2020 年 国内电动汽车车载充电机市场规模将达到 77 亿元。 本文将给大家介绍基于 TI C2000™ 微控制器的 3.3KW 车载充电机方案。此参考设计使用 C2000™ 微控 制器 (MCU) 和 LMG3410 来控制交错式连续导通模式 (CCM) 图腾柱 (TTPL) 无桥功率因数校正 (PFC) 功率级的方法。该电源拓扑采用氮化镓 (GaN) 器件， 从而提高了效率，并降低了电源尺寸。该设计支持用于提高效率的切相和自适应死 区时间，用于在轻负载下改进功率因数的输入电容补偿方案，以及瞬态时用于降低 电压尖峰的非线性电压环路。 交错式 TTPL PFC 拓扑结构是电动汽车充电器的设计的趋势，具有更高功率和更 高的功率密度。 C2000 MCU 是针对实时控制应用而优化的 MCU 系列之一。 快速优质的模数控制器可精确测量电流和电压信号，集成比较器子系统 （CMPSS）提供过流和过压保护，而无需使用任何外部设备。经过优化的 CPU 内核可以快速执行控制循环。 三角函数使用片上三角数学单元（TMU）可以加速 操作。 该解决方案还选择在 F28004x 和 F2837x 上使用控制律加速器 （CLA）， CLA 是协处理器可用于减轻 CPU 负担并在 C2000 上启用运行更快 的循环或更多功能

中文分词一直都是中文自然语言处理领域的基础研究。目前，网络上流行的很多中文分词软件都可以在付出较少的代价的同时，具备较高的正确率。而且不少中文分词软件支持Lucene扩展。但不管实现如何，目前而言的分词系统绝大多数都是基于中文词典的匹配算法。其中最为常见的是最大匹配算法 (Maximum Matching，以下简称MM算法) 。MM算法有三种：一种正向最大匹配，一种逆向最大匹配和双向匹配。本程序实现了正向最大匹配算法。