Raptor VeeCAN: Difference between revisions

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==Simulation==
==Simulation==
<p>The Raptor VeeCAN simulator creates a strong link from the software development cycle to the hardware testing cycle. Typically, these would be two distinct, time-consuming phases, but with strong coupling of the simulator and the hardware (hardware-in-the-loop simulation) and with real-time debugging iteration time is drastically reduced.  '''[[Raptor_Display_Examples| Click here]]''' to view and test some Raptor Simulators.</p>
<p>The Raptor VeeCAN simulator creates a strong link from the software development cycle to the hardware testing cycle. Typically, these would be two distinct, time-consuming phases, but, with strong coupling of the simulator and the hardware (hardware-in-the-loop simulation) and with real-time debugging, iteration time is drastically reduced.  '''[[Raptor_Display_Examples| Click here]]''' to view and test some Raptor Simulators.</p>


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<gallery widths=222px heights=222px perrow=3>

Revision as of 14:11, 2 March 2023

New Eagle > Products Wiki > Raptor VeeCAN

Overview

New Eagle’s line of Raptor Displays and complimentary Raptor-Dev software offer an alternative approach to the traditional programming languages: These displays allow developers to leverage the graphical programming environment of MATLAB Simulink to quickly and easily create, edit and debug display software. All Raptor displays are capable of interfacing with any CAN-based actuators or sensors. The Raptor VeeCAN 800 and VeeCAN 320, in particular, have a number of analog and frequency inputs and digital outputs, making these displays ideal all-in-one display/controller solutions for a wide variety of applications. 

PDF Raptor VeeCAN Overview

Raptor Platform Information


To view a full list of the Raptor VeeCAN displays, click here.

VeeCAN Libraries

For information on the blockset libraries that support VeeCAN, click here.

Custom libraries are a useful tool in the Raptor Platform, because not only can custom, prefabricated libraries be imported, user-made ones are also possible.

CAN Development

CAN development within the Raptor framework integrates industry-standard DBC files. This allows for quick sharing of a CAN protocol both within and outside the Raptor framework. The image below shows the configuration screen of a CAN Rx message block after a DBC file is selected.


Selection of a CAN automatically populates signal output specifications on the Raptor CAN message blocks with the information contained in the DBC file, as shown in the image below.

Raptor VeeCAN Example

The image below is a basic Raptor VeeCAN project. It demonstrates separation of HMI logic from the control and signal logic. This is a stylistic approach to ensure easy transferability of logic to and from other Raptor platforms that do not have HMI functionality.


Learn more about our Raptor Platform here.

View example Raptor displays here.

VeeCAN Display Development

The Raptor HMI blocks were designed both to allow ease of use and to allow low-level control of display features. In the RVC library you will find high level blocks to quickly display an assortment of information and graphics, such as: lists, menus, gauges, images and text strings. These high-level blocks have been designed from a primitive block set, meaning that tweaks can be made to these under-the-covers primitives to configure the display to your taste or to help you create your own display screens from scratch. The images below demonstrate a gauge block and a subset of the primitive blocks within it.

Simulation

The Raptor VeeCAN simulator creates a strong link from the software development cycle to the hardware testing cycle. Typically, these would be two distinct, time-consuming phases, but, with strong coupling of the simulator and the hardware (hardware-in-the-loop simulation) and with real-time debugging, iteration time is drastically reduced. Click here to view and test some Raptor Simulators.