گروه خدمات فنی مهندسی رهگشافن

# Access to ECU physical values (DAQ and STIM
lists) for measurement and simulation applications
# Universal Measurement
and Calibration Protocol (XCP) master functionality on CAN and Ethernet
# CAN
Calibration Protocol (CCP) Version 2.1 support
# Compatibility with all NI
PCI, PXI, and PCMCIA CAN Series 2 interfaces
# Ability to import ASAM-defined
(*.A2L) database files
# Included detailed shipping examples as starting
points for measurement and calibration applications
# Access to internal ECU
characteristics (1D to 3D) for calibration applications

The National
Instruments ECU Measurement and Calibration Toolkit extends the NI LabVIEW, NI
LabWindows/CVI, and Microsoft C/C++ development environments to support
measurement and calibration applications for the design and validation of
electronic control units (ECUs). The NI ECU Measurement and Calibration Toolkit
provides high-level, easy-to-use functions based on the Universal Measurement
and Calibration Protocol (XCP) and CAN Calibration Protocol (CCP). Because of
these protocols, you can read and write to internal ECU variables and
characteristics as defined in ASAM (.A2L) database files. By using (.A2L)
database files, the toolkit automatically applies all scaling information and
returns data in engineering units for easy analysis, presentation, and logging.
In addition, the toolkit offers high-quality examples for typical use case
applications such as how to measure ECU variables or how to manipulate ECU
characteristics using 1D to 3D user interfaces.

# Built-in user libraries for DAQ, GPIB,
VXI, and more
# Integrated ANSI C development environment
# Libraries for
advanced data analysis
# Rapid application development with
Code-Builder

# Facilitate easier development with Express VIs
# Switch
between supported DSP targets without changing application significantly
#
Use hundreds of prebuilt DSP functions for faster development
# Implement
digital filters designed using the LabVIEW Digital Filter Design Toolkit
#
Focus more on concepts and less on implementation details with interactive
environment
# Debug intuitively through real-time interaction with
front-panel s

With the National Instruments LabVIEW DSP Module, you
can graphically program several real-time DSP boards.
Based on NI LabVIEW,
an industry-standard tool for design, measurement, and control, the interactive,
easy-to-use nature of the NI LabVIEW DSP Module helps you easily build
applications quickly, even if you are not familiar with DSP. The LabVIEW DSP
Module comes with an extensive library of signal processing algorithms to help
design, test, and prototype your application. The LabVIEW DSP Module also works
with multiple DSP targets to provide a choice of hardware for final
implementation.

Students and professors can use the LabVIEW DSP Module to
graphically design and implement DSP systems. The LabVIEW DSP Module is based on
National Instruments LabVIEW, an industry-standard tool for design, measurement,
and control. The interactive nature of the LabVIEW DSP Module makes it easy for
students who are new to DSP to build applications. The LabVIEW DSP Module
facilitates deploying the DSP application to real-time targets so students can
see and hear the DSP process live data in real time. With the LabVIEW DSP Module
graphical environment, professors can spend more teaching time focusing on DSP
concepts rather than implementation details. DSP targets include the NI
SPEEDY-33 DSP board and Texas Instruments DSK6711 and DSK6713 targets.

National Instruments Vision Builder for Automated Inspection
(AI) is a configurable machine vision development environment that requires no
programming. With Vision Builder AI, you can solve most machine vision
application challenges without the use of a programming language or complicated
customization tools. Vision Builder AI includes NI Vision Acquisition software,
a set of drivers and utilities that acquire, display, and save images from any
NI frame grabber, GigE Vision camera, or IEEE 1394 camera. With NI Vision
Builder AI, you can:

* Acquire and process images with any NI frame
grabber, GigE Vision or IEEE 1394 cameras, or the NI Compact Vision System
*
Build, benchmark, and deploy complete machine vision applications without
programming
* Configure more than 100 powerful machine vision tools including
geometric matching, OCR, and particle analysis
* Communicate triggering and
inspection results directly to industrial devices over digital I/O, serial and
Ethernet protocols[/center]

The Vision Builder AI interface contains the
following four areas:
1. Main window—Displays the image being processed, the
Decision Making property page, the Serial I/O property page, and the Configure
Inputs/Outputs property page.
2. Inspection diagram window—Displays the
sequence of Vision Builder AI steps that comprise the inspection.
3. Embedded
help window—Contains context-sensitive help about when to use a step, how to
configure a step, the function of the user-interface controls, and frequently
asked questions.
4. Inspection Steps palette—Lists and describes the steps
you use to create your inspection. When you click most steps, this palette
transforms into the property page for the step.

The MATRIXx Basics course prepares you to use the
MATRIXx product family. The student will learn how to build and analyze models,
run simulations, compare simulation results, and generate and execute AutoCode
in nonreal-time. The course includes both lecture and hands-on exercises. This
is a very practical, results-oriented course, which will provide knowledge and
skills that can be applied immediately.

The National
Instruments Modulation Toolkit extends the built-in analysis capability of
LabVIEW with functions and tools for signal generation, analysis, visualization,
and processing of standard and custom digital and analog modulation formats.
With this toolkit, you can rapidly develop custom applications for research,
design, characterization, validation, and test of communications systems and
components that modulate or demodulate signals. Applications for the NI
Modulation Toolkit are numerous; they include digital modulation formats (AM,
FM, PM, ASK, FSK, MSK, GMSK, PSK, QPSK, PAM, and QAM) that are the foundation of
many digital communication standards found in 802.11a/b/g/n, ZigBee (802.15.4),
WiMAX (802.16), RFID, satellite communications, and commercial broadcast among
others.

For RF applications, the NI Modulation Toolkit complements the
National Instruments PXI-5660 RF Vector Signal Analyzer and the PXI-5671 RF
Vector Signal Generator. For lower frequency operation (baseband or IF signals)
the Modulation Toolkit works with the 100 MHz mixed-signal test platform with
digitizer, analog waveform generator, and digital waveform I/O products.

#
Connect a LabVIEW user interface with your simulation model running in The
MathWorks, Inc. Simulink®
# Use LabVIEW to interact with your models
developed using the Simulink software
# Connect your model to real-time IO
for prototyping, deployment, and HIL simulation
# Easily add data
acquisition, CAN and FPGA I/O through a configuration-based dialog
# Apply
stimulus to your model using multi-channel data profiles
# Specify multirate
data logging on a per channel basis to optimize file size and application
performa
Overview
The National Instruments LabVIEW Simulation Interface
Toolkit gives control system design and test engineers a link between NI LabVIEW
and The MathWorks, Inc. Simulink® software. With the NI LabVIEW Simulation
Interface Toolkit, you can easily build custom LabVIEW user interfaces to view
and control your simulation model during run time. This toolkit also provides a
plug-in for The MathWorks, Inc. Real-Time Workshop® to import your models
created in the Simulink environment into LabVIEW allowing you to connect your
model to the real world through a variety of real-time I/O platforms (requires
LabVIEW Real-Time). With these capabilities, you can easily take your models
from software verification to real-world prototyping and hardware-in-the-loop
simulation.

Verify Models with a LabVIEW User Interface
The NI LabVIEW
Simulation Interface Toolkit enables you to build custom user interfaces for
models created in the Simulink environment. The SIT Connection Manager offers a
configuration-based utility to connect a custom LabVIEW user interface to your
models, eliminating the need for any programming knowledge. The custom user
interface enables you to easily simulate, analyze, and verify your control model
on a desktop PC. Creating a custom user interfaces for your simulation model is
accomplished in four steps:

Step 1. The LabVIEW Simulation Interface
Toolkit adds a SignalProbe block to the Simulink environment. Place the
SignalProbe in the top level of your model to enable LabVIEW to communicate with
your model while it is running in the Simulink environment.
Step 2. Create a
LabVIEW user interface by placing controls and indicators on a LabVIEW front
panel.
Step 3. Use the SIT Connection Manager to specify the links between
the LabVIEW user interface and your model.
Step 4. Start your simulation in
the Simulink environment by selecting run in your LabVIEW user
interface.

Deploying Models to Real-Time Hardware
The LabVIEW
Simulation Interface Toolkit also provides a plug-in for The MathWorks, Inc.
Real-Time Workshop® software that helps facilitate the importation of your
models into LabVIEW. When used with LabVIEW Real-Time, this capability allows
you to connect your model to the real world through a variety of real-time I/O
platforms and still provides the user interface capabilities utilized in the
verification of the model. The LabVIEW environment allows you to select the
appropriate real-time platform based on the performance, portability, and
durability requirements of your application.

The LabVIEW Simulation
Interface Toolkit makes it easy to connect your models to a combination of
analog, digital, and protocol-based I/O devices using the SIT Connection
Manager. In addition to the user interface and I/O configuration, this utility
also enables you to easily add stimulus to your application using multichannel
data profiles. You also can specify multirate data logging on a per-channel
basis to optimize file size and application performance. All of these
capabilities can be configured without programming; however, you can further
customize your configurations and add more features using LabVIEW graphical
programming.