Windows系统下(Linux和MAC系统下请自行了解清楚)NI的各种软件、模块、工具包、驱动程序,使用NI许可证管理器来激活的,绝大部分的都可以使用NI Lincense Activator来激活,以下链接可下载:
NI序列号Serial Number生成激活工具NI License Activator,LabVIEW/VBAI/VDM/VAS等软件模块工具包破解工具不限版本
http://pcmv.cn/thread-490-1-1.html
视觉论坛的各种资源,除了视觉相关的模块有使用外,大部分的都不会使用,所以仅提供资源不能提供技术支持。资源的下载地址一般会同时提供NI官方地址和百度网盘的下载地址。某些工具包NI的地址失效或没有NI的下载地址,那视觉论坛也没有办法,只能尝试使用百度网盘地址下载;如果百度网盘的下载地址失效过期,可联系论坛客服更新。现在NI的下载服务器对我国IP地址不是很友好,有些时候速度很慢或大的资源下载很容易出错,这样会造成安装过程各种类型报错而无法安装。建议在下载完成后,对下载资源做校验和验证(NI一般会提供MD5或SHA256等),与官方或视觉论坛提供的校验和对比,一致就可以安装,如果不一致,则需要重新下载。视觉论坛早期下载的资源,那时候NI没有这么多限制,基本上都是正常下载的资源;后期下载的资源,都与NI的正确校验和对比过,保证是正确的资源才上传到百度网盘,所以百度网盘的资源基本上是正确的。校验和工具下载地址:
文件Hash计算器FHash,文件校验和验证下载文件正确性验证,MD5值计算、SHA1值计算、SHA256值计算、CRC32值计算
http://pcmv.cn/thread-26524-1-1.html
LabVIEW 8.2 Control Design 2.1.2 Win32Eng LabVIEW8.2控制设计CD2.1.2
LabVIEW控制设计与仿真模块可用于仿真动态系统、设计控制器,并将控制系统部署至实时硬件。
LabVIEW控制设计与仿真模块是一款与LabVIEW平台相集成的附加软件,提供了内置并行机制、多核和多速率技术等编程能力以及用来部署至实时硬件的工具。您可将测量功能集成到用于系统识别、模型校准或模型验证的设计中。然后将算法部署至NI实时嵌入式硬件,实现快速控制原型和硬件在环(HIL)应用。
发布日期
2007/1/3
包含的版本
2.1.2完整版
受支持的操作系统
Windows 2000
Windows XP 32-bit
Windows Vista
语言
English
程序位数
32位
校验和
文件大小: 288115705 字节 (274.77 MB)
修改日期: 2019-12-17 11:04
MD5: dee80c537e5a280f1dcc48d11cdab51f
SHA1: 6825532a3de1e9893b47696cddbc1a0656fcfb83
SHA256: f6f4a89ce3ed3de041ff1a9eac62266d9e75890667493a75c5fbbfa5a0fbc2a8
CRC32: 16efc616
百度网盘和NI官方下载地址:
请注册登陆视觉论坛会员,购买附件查看
LabVIEW 8.2 Control Design 2.1.2 Win32Eng LabVIEW8.2控制设计CD2.1.2
http://pcmv.cn/thread-28621-1-1.html?fromuid=9
(出处: 视觉论坛VISIONBBS|视觉之家VISIONHOME)
LabVIEW Control Design Toolkit 2.1.2 Readme
Launch LabVIEW.
Select Tools»Advanced»Mass Compile.
Browse to the labviewi.libddonsControl Design folder.
Click Current Folder. LabVIEW displays the Mass Compile dialog box.
Click Mass Compile to start mass compiling this folder.
labviewexamplesControl Design
labviewi.libimathengineslvmathPlug InControl Design
Known Issues
The Control Design Toolkit 2.1.2 installer does not install this readme file to the labview eadme directory. The installer installs the Control Design Toolkit 2.1.1 readme file instead.
The Control Design Assistant 2.1.2 does not support Microsoft Windows Vista. Additionally, the Control Design Assistant 2.1.2 supports only SignalExpress 1.x.
After installing CD 2.1.2, the plus and minus MathScript functions do not work properly. Workaround: Use the + and – operators instead.
If you are using Internet Explorer 7 on Microsoft Windows Vista, clicking an external link in the LabVIEW Help might display a JavaScript error while displaying the linked page. An external link is a link to a Web site or other place outside the LabVIEW Help. You can ignore this JavaScript error because the script has run already and the page displays properly. If Internet Explorer prompts you to continue running scripts, click the Yes button to close the dialog box and continue.
LabVIEW Control Design Toolkit 2.1.1 Readme
LabVIEW Control Design Toolkit 2.1 Readme
Overview
What's New in 2.1
System Requirements
National Instruments LabVIEW 8.0, Full or Professional Development Systems
Installation Instructions
Insert the LabVIEW Control Design Toolkit CD.
Run the setup.exe program.
Follow the instructions that appear on the screen.
Accessing the Help
Launch LabVIEW.
Select Help»Search the LabVIEW Help from the pull-down menu to launch the LabVIEW Help.
Click the Contents tab.
Navigate to Toolkits»Control Design VIs & Functions.
Finding Examples
Changes from 2.0
The CD Construct Special TF Model VI replaces the CD Construct Special Model VI.
Use the CD Construct PID Model VI to construct a PID model in academic, series, or parallel form.
Use the CD Construct Lead-Lag Controller VI to construct a phase-lead or phase-lag controller model.
Use the CD Construct Filter Model VI to construct a digital filter model from direct coefficients of the inverse power of z or from filter design specifications.
Use the CD Draw State-Space Equation VI to render a state-space equation on the front panel.
Use the CD Zeros VI to return the zeros of a model.
Use the CD Poles VI to return the poles of a model.
LabVIEW no longer supports the CD Construct Special Model VI. Use the CD Construct Special TF Model VI or the CD Construct PID Model VI instead.
The Control Design Toolkit no longer uses special indicators for Nichols, Nyquist, Root-Locus, and Pole-Zero plots. These indicators now are standard LabVIEW graphs. You now can right-click the output terminals of these VIs and select Create»Indicator to create Nichols, Nyquist, Root-Locus, or Pole-Zero Map plots on the front panel.
If you open a VI saved in the Control Design Toolkit 2.0, the CD Parametric Time Response VI, CD Root Locus VI, and CD Pole-Zero Map VI icons appear with a red banner. The data types of the plot indicators of these VIs have changed. You must navigate to the VI on the appropriate palette and place the VI on the block diagram again. You also must create new plot indicators using the updated VIs.
The CD Parametric Time Response VI has three new polymorphic instances. Use these External instances to calculate parametric information using a set of previously-calculated time response data. Additionally, you now can choose whether this VI uses a step, impulse, or initial responses to obtain the time response data. For state-space models, you also can choose whether you want the time response data for the model states or outputs. This VI also returns the Peak Value of the time response data.
The Rise Time Thresholds (%) control of the CD Parametric Time Response VI now has only two parameters, Lower and Upper, that define the rise time thresholds.
The Gain Type parameter of the CD Ackerman and CD Pole Placement VIs now has options for choosing whether you want the Controller gain, Current Observer gain, or Predictive Observer gain. Use the Current Observer gain and the Predictive Observer gain with the CD Current Observer VI and CD Predictive Observer VI, respectively. Use either gain type for the CD Continuous Observer function.
The CD Kalman Gain VI now has four polymorphic instances that compute the Kalman gain matrix L for continuous and discrete stochastic and deterministic models. You also can use this VI to discretize internally a continuous model before computing L.
The CD Linear Quadratic Regulator now has a Discretized LQR instance. Use this instance to discretize internally a continuous model before computing K.
The CD Controllability Matrix VI has a new output, Is Stabilizable?
The CD Observability Matrix VI has a new output, Is Detectable?
The default values of the Input (column) and Output (row) parameters of the CD Draw Transfer Function Equation VI and the CD Draw Zero-Pole-Gain Equation VI now are –1, which specifies that these VIs draw all inputs and outputs. A value of 0 now specifies these VIs draw the first input or output of the equation.
The CD Draw Transfer Function Equation VI and the CD Draw Zero-Pole-Gain Equation VI have the following new inputs: Format Coefficients, Origin, and Function Name.
In the Control Design Toolkit 2.0, the CD Draw Transfer Function Equation VI and the CD Draw Zero-Pole-Gain Equation VI render equations at an Origin of (20, 20) even though you cannot control this location. In the Control Design Toolkit 2.1, the default value for this parameter is (10, 10). To draw the equations in the same location as in version 2.0, wire a constant value of (20, 20) to the Origin input.
The CD All Margins VI and the CD Gain and Phase Margin VI have a new polymorphic instance, Frequency Response Data. Use this instance to determine the margins for a set of stand-alone frequency response data without wiring in a model.
The CD Bode, CD Nichols, CD Nyquist, and CD Singular Values VIs now accept either a specified range of frequency information or a vector of frequency values. The Frequency Info input to these VIs now is the Frequency Range input.
The CD Root Locus VI now has a Gain input. Use this input to adjust the feedback gain as you view the pole locations.
The Model Information VIs palette now is located under the Control Design VIs palette instead of the Model Construction VIs palette.
Known IssuesControl Design VIs
When using the CD Pole Placement VI, if the desired poles are sufficiently close to the open-loop poles, the gain does not place the poles in the desired locations.
The CD Parametric Time Response VI calculates rise time by performing a step response and measuring the time it takes to go from 10% to 90% (default values) of the final steady-state value. If a system has a step response where the initial overshoot is in a direction opposite to that of the final steady-state value, that portion of the step response does not affect the calculation of the rise time.
When calculating the Input-State DC Gain value of the CD DC Gain VI for a state-space model that has a pure integrator, the VI returns Inf.
Control Design Assistant
The User-Defined step does not work with LabVIEW 8.0.
Control Design MathScript Functions
The LabVIEW MathScript window might not display multiple-input multiple-output (MIMO) system label plots correctly for time and frequency responses. Also, you might not be able to add grids to a subplot.
You cannot make root locus plots part of subplots.
In the LabVIEW MathScript environment, transfer function polynomial coefficients always are in descending order. However, the Control Design VIs assume these coefficients are in ascending order.
Documentation
Some help topics for the Control Design VIs and Functions include links to topics related to the LabVIEW Simulation Module. These links will be broken if you have not installed the Simulation Module.
The Detailed Help link for the CD Construct Special TF Model VI links to the help for the CD Construct Special Model VI.
The user manual and help refer to the CD Root Locus with Gain VI. The correct name is the CD Root Locus VI.
The Context Help window of the CD State Feedback Controller VI does not contain a Detailed Help link.