Control Design And Simulation Module Labview 2015 Keygen _HOT

Control Design And Simulation Module Labview 2015 Keygen

How to Use LabVIEW Control Design and Simulation Module 2015

LabVIEW Control Design and Simulation Module 2015 is an add-on software that integrates with the LabVIEW programming environment to offer capabilities such as built-in parallelism, multicore, and multirate technologies as well as tools for deploying to real-time hardware[^1^]. It helps you simulate dynamic systems, design controllers, and implement control algorithms on NI hardware platforms such as CompactRIO, PXI, and NI RIO devices.

In this article, we will show you how to use LabVIEW Control Design and Simulation Module 2015 to create and test a PID controller for a DC motor. We will also show you how to generate a keygen for activating the software.

Step 1: Install LabVIEW Control Design and Simulation Module 2015

To install LabVIEW Control Design and Simulation Module 2015, you need to have LabVIEW 2015 or later installed on your computer. You can download LabVIEW Control Design and Simulation Module 2015 from the NI website[^1^] or use the installation media that came with your purchase. Follow the instructions on the screen to complete the installation process.

Step 2: Create a PID Controller for a DC Motor

To create a PID controller for a DC motor, you need to use the Control Design Assistant, which is a graphical tool that helps you design and analyze control systems. You can access the Control Design Assistant from the Tools menu in LabVIEW.

The Control Design Assistant allows you to create models of your plant and controller, perform linear analysis, design compensators, and simulate your control system. You can also import or export models from other software such as MATLAB or Simulink.

In this example, we will use a simple model of a DC motor with an armature resistance of 1 ohm, an armature inductance of 0.5 henry, a back-emf constant of 0.01 volt-second per radian, a torque constant of 0.01 newton-meter per ampere, a moment of inertia of 0.01 kilogram-square meter, and a viscous friction coefficient of 0.1 newton-meter-second per radian. The input voltage is limited to +/- 10 volts and the output angular position is measured by an encoder with a resolution of 360 pulses per revolution.

To create this model in the Control Design Assistant, follow these steps:

Click on the New button in the toolbar to create a new project.

Click on the Plant tab and select Transfer Function from the Model Type drop-down menu.

Enter the following numerator and denominator coefficients for the transfer function that represents the DC motor:

Numerator: [0.01]

Denominator: [0.005 0.11 0.01]

Click on the Apply button to update the model.

Click on the Input/Output tab and select Voltage as the input signal type and Position as the output signal type.

Enter -10 and 10 as the minimum and maximum values for the input signal.

Enter 0 and 6.28 as the minimum and maximum values for the output signal.

Click on the Apply button to update the model.

You should see something like this:

![DC motor model](https://i.imgur.com/7y4v8Zu.png)

To design a PID controller for this model, follow these steps:

Click on the Controller tab and select PID from the Controller Type drop-down menu.

Enter 1 as the proportional gain (Kp), 0.1 as the integral gain (Ki), and 0.01 as the derivative gain (Kd).

Click on the Apply button to update the controller.

Click on the Analysis tab and select Root Locus from the Analysis Type drop-down menu.

Click on the Plot button to see how the closed-loop poles vary with different values of Kp.

![Root locus plot]( 66dfd1ed39

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