These are the two repositories we created in the GitHub Setup section. The value fields for these variables should be your organization’s name (instead of ‘branchNI’) and myPicRepo, respectively. For instance, you may use something like C:\Windows\Temp\jenkins.Ĭlick Add two more times to add the ORG_NAME variable and the PIC_REPO variable. This should be an empty local directory anywhere on your computer, that LabVIEW will build and output files to. Fill out the Name as shown below (BUILD_SYSTEM_REPO), and enter myBuildSystem in the Value field:Ĭlick Add another time and add the LV_BUILD_OUTPUT_DIR environment variable. Navigate to the Global properties section.Ĭheck the Environment variables box to display the List of variables.Ĭlick Add to add a new environment variable. The Connector Pane connects the controls and indicators together to create a SubVI.From the Jenkins dashboard, navigate to the system configuration page: Manage Jenkins > Configure System The Icon is the visual representation that includes the image and text of the VI. The Connector and Icon Pane are in the upper right corner of the graphical user interface.
The Block Diagram uses graphical source code to let you write functions and structures that deliver outputs. Drag and drop controls and indicators let you easily build custom user interfaces.
You can change the numerical values to manipulate the outcome. The inputs are known as controls whereas the outputs are called indicators.
The Front Panel is the user interface that gives you input and output. The active VIs will be listed above the menu bar. The VIs in LabVIEW contains a Front Panel, Block Diagram, and Connector/Icon Pane. The programs that LabVIEW uses are called Virtual Instruments. However, data migration from LabVIEW into a database can be difficult. You can quickly build simple projects or complex processes.
The visual approach that the software takes is easier to understand than linear coding. LabVIEW is one of the easiest programming environments to use. LabVIEW is also compatible with additional code languages like C and C++. National Instruments created the programming language G to make coding easier, but you are not required to use this language. The platform exposes you to the graphical programming language called G. A large library of compatible add-on algorithms is available to integrate into LabVIEW.
Analysis and signal processing algorithms let you learn about your experiments. PID algorithms are already included in the software package. An extensive hardware integration suite is available for a variety of electronic devices: benchtop instruments, FPGA-based embedded computer hardware, PC-based data acquisition boards, software-defined radios, etc. LabVIEW is commonly used to control instruments to make accurate measurements. The graphical user interface lets you easily visualize parallelism in your code with charts. You can restructure coding errors that appear in real-time instead of at the end of projects since the code is automatically kept current. The code will be recompiled with each new action that you make. You can move info between functions in the interactive user interface. Visual diagrams can mirror thought processes. Your projects are easy to comprehend since the presentations are presented in illustrative charts instead of linear code. You can easily develop conclusions in the graphical user interface. LabVIEW is an ideal solution for people that are new to programming. You can run multiple tests to receive valuable test results directly in the user interface. LabVIEW can deliver reports on automated tests to let you know whether a device or unit has passed or failed. The visual approach to programming lets you intuitively populate the data into flow charts. LabVIEW is used to organize scientific and technical data.