National Instruments Network Card NI DNET User Manual

T
DeviceNet  
TM  
NI-DNET User Manual  
NI-DNET User Manual  
May 2004 Edition  
Part Number 370375B-01  
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Important Information  
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The CAN/DeviceNet hardware is warranted against defects in materials and workmanship for a period of one year from the date of shipment,  
as evidenced by receipts or other documentation. National Instruments will, at its option, repair or replace equipment that proves to be defective  
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Under the copyright laws, this publication may not be reproduced or transmitted in any form, electronic or mechanical, including photocopying,  
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Trademarks  
CVI, LabVIEW, National Instruments, ni.com, NI-CAN, and NI-DNETare trademarks of National Instruments Corporation.  
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Patents  
For patents covering National Instruments products, refer to the appropriate location: Help»Patents in your software, the patents.txtfile  
on your CD, or ni.com/patents.  
WARNING REGARDING USE OF NATIONAL INSTRUMENTS PRODUCTS  
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About This Manual  
How to Use the Manual Set ...........................................................................................ix  
Chapter 1  
NI-DNET Objects..........................................................................................................1-4  
Interface Object ...............................................................................................1-5  
I/O Object........................................................................................................1-6  
NI-DNET Hardware Overview  
Chapter 3  
LabVIEW ........................................................................................................3-1  
LabWindows/CVI............................................................................................3-2  
Microsoft Visual Basic....................................................................................3-2  
Microsoft C/C++ .............................................................................................3-3  
Borland C/C++ ................................................................................................3-3  
Other Programming Languages.......................................................................3-4  
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Contents  
Addition of Slave Connections after Communication Start ............. 3-9  
Step 4. Stop Communication .......................................................................... 3-10  
Multiple Applications on the Same Interface................................................................ 3-10  
Chapter 4  
Get and Set Attributes in a Remote DeviceNet Device .................................. 4-12  
Other Explicit Messaging Services................................................................. 4-13  
Configuration .................................................................................................. 4-14  
Physical Characteristics of DeviceNet .......................................................................... A-2  
General Object Modeling Concepts .............................................................................. A-2  
Object Modeling in the DeviceNet Specification.......................................................... A-3  
Explicit Messaging Connections................................................................................... A-5  
I/O Connections............................................................................................................. A-7  
Assembly Objects.......................................................................................................... A-11  
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Power Supply Information for the DeviceNet Ports......................................................B-3  
Cable Specifications ......................................................................................................B-6  
Maximum Number of Devices ......................................................................................B-6  
Appendix C  
Troubleshooting with the Measurement & Automation Explorer (MAX)....................C-1  
Troubleshooting Self Test Failures................................................................................C-2  
Common Questions........................................................................................................C-3  
Appendix D  
Technical Support and Professional Services  
Glossary  
Index  
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About This Manual  
This manual describes the basics of DeviceNet and explains how to  
develop an application program, including reference to examples. The user  
manual also contains hardware information.  
How to Use the Manual Set  
Installation Guide  
(CD Sleeve)  
Software and  
Hardware  
Installation  
First-Time  
NI-DNET Users  
Experienced  
NI-DNET Users  
NI-DNET  
Programmer  
Reference Manual  
NI-DNET  
User Manual  
Application  
Development  
and Examples  
Function  
and Object  
Descriptions  
Use the installation guide to install and configure your DeviceNet hardware  
and the NI-DNET software.  
Use this NI-DNET User Manual to learn the basics of DeviceNet and how  
to develop an application program. The user manual also contains  
information on DeviceNet hardware.  
Use the NI-DNET Programmer Reference Manual for specific information  
about each NI-DNET function and object.  
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About This Manual  
Conventions  
The following conventions appear in this manual:  
»
The » symbol leads you through nested menu items and dialog box options  
to a final action. The sequence File»Page Setup»Options directs you to  
open the File menu, select the Page Setup item, and select Options from  
the last dialog box.  
This icon denotes a note, which alerts you to important information.  
bold  
Bold text denotes items that you must select or click on in the software,  
such as menu items and dialog box options. Bold text also denotes  
parameter names.  
italic  
Italic text denotes variables, emphasis, a cross reference, or an introduction  
to a key concept. This font also denotes text that is a placeholder for a word  
or value that you must supply.  
monospace  
Text in this font denotes text or characters that you should enter from the  
keyboard, sections of code, programming examples, and syntax examples.  
This font is also used for the proper names of disk drives, paths, directories,  
programs, subprograms, subroutines, device names, functions, operations,  
variables, filenames, and extensions.  
Related Documentation  
The following documents contain information that you might find helpful  
as you read this manual:  
ANSI/ISO Standard 11898-1993, Road Vehicles—Interchange of  
Digital Information—Controller Area Network (CAN) for High-Speed  
Communication  
DeviceNet Specification, Version 2.0, Open DeviceNet Vendor  
Association  
CompactPCI Specification, Revision 2.0, PCI Industrial Computers  
Manufacturers Group  
PXI Hardware Specification, Revision 2.1, National Instruments  
Corporation  
PXI Software Specification, Revision 2.1, National Instruments  
Corporation  
NI-DNET User Manual  
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About This Manual  
LabVIEW online reference  
ODVA website, www.odva.org  
Microsoft Win32 Software Development Kit (SDK) online help  
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1
NI-DNET Software Overview  
The DeviceNet software provided with National Instruments DeviceNet  
hardware is called NI-DNET. This section provides an overview of the  
NI-DNET software.  
Installation and Configuration  
Measurement & Automation Explorer (MAX)  
Measurement & Automation Explorer (MAX) provides access to all of  
your National Instruments products. Like other NI software products,  
NI-DNET uses MAX as the centralized location for all configuration  
and tools.  
To launch MAX, select the Measurement & Automation shortcut on your  
desktop, or within your Windows Programs menu under National  
Instruments»Measurement & Automation.  
For information about the NI-DNET software within MAX, consult the  
MAX online help. A reference is in the MAX Help menu under  
Help Topics»NI-DNET.  
View help for items in the MAX Configuration tree by using the built-in  
MAX help pane. If this help pane is not shown on the far right, select the  
Show/Hide button in the upper right.  
View help for a dialog box by selecting the Help button in the window.  
The following sections provide an overview of some common tasks you  
can perform within MAX.  
Verify Installation of Your DeviceNet Hardware  
Within the Devices & Interfaces branch of the MAX Configuration tree,  
NI DeviceNet cards are listed along with other hardware in the local  
computer system, as shown in Figure 1-1.  
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Figure 1-1. NI-DNET Cards Listed in MAX  
Note Each card’s name uses the word CAN, because the Controller Area Network is the  
communication protocol upon which DeviceNet is built.  
If your NI DeviceNet hardware is not listed here, MAX is not configured  
to search for new devices on startup. To search for the new hardware,  
press <F5>.  
To verify installation of your DeviceNet hardware, right-click the  
DeviceNet card, then select Self-test. If the self-test passes, the card icon  
shows a checkmark. If the self-test fails, the card icon shows an X mark, and  
the Test Status in the right pane describes the problem. Refer to  
Appendix C, Troubleshooting and Common Questions, for information  
about resolving hardware installation problems.  
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Configure DeviceNet Port  
The physical port of each DeviceNet card is listed under the card’s name.  
To configure software properties, right-click the port and select  
Properties.  
In the Properties dialog, you assign an interface name to the port, such as  
DNET0 or DNET1. The interface name identifies the physical port within  
NI-DNET APIs.  
Change Protocol  
To change the default protocol for the DeviceNet (CAN) card, right-click  
the card and select Protocol. In this dialog you can select either DeviceNet  
for NI-DNET (default), or CAN for NI-CAN. For more information, refer  
to the section Using NI-CAN with NI-DNET.  
LabVIEW Real-Time (RT) Configuration  
LabVIEW Real-Time (RT) combines easy-to-use LabVIEW programming  
with the power of real-time systems. When you use a National Instruments  
PXI controller as a LabVIEW RT system, you can install a PXI DeviceNet  
card and use the NI-DNET APIs to develop real-time applications. For  
example, you can control a network of DeviceNet devices as a master, and  
write your control algorithm in LabVIEW.  
When you install the NI-DNET software, the installer checks for the  
presence of the LabVIEW RT module. If LabVIEW RT exists, the  
NI-DNET installer copies components for LabVIEW RT to your  
Windows system. As with any other NI product for LabVIEW RT, you then  
download the NI-DNET and NI-CAN software to your LabVIEW RT  
system using the Remote Systems branch in MAX. For more information,  
refer to the LabVIEW RT documentation.  
After you have installed your PXI DeviceNet cards and downloaded the  
NI-DNET software to your LabVIEW RT system, you need to verify  
the installation. Within the Tools menu in MAX, select NI-DNET»  
RT Hardware Configuration. The RT Hardware Configuration tool  
provides features similar to Devices & Interfaces on your local system.  
Use the RT Hardware Configuration tool to self-test the DeviceNet cards  
and assign an interface name to each physical DeviceNet port.  
Tools  
NI-DNET provides tools that you can launch from MAX.  
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NI-Spy  
This tool monitors function calls to the NI-DNET APIs. This tool helps in  
debugging programming problems in your application. To launch this tool,  
open the Software branch of the MAX Configuration tree, right-click  
NI Spy, and select Launch NI Spy.  
SimpleWho  
To provide valid parameters for the NI-DNET open functions  
(ncOpenDnetIntf, ncOpenDnetExplMsg, and ncDnetOpenIO), you  
need to determine some basic information about your DeviceNet devices.  
This information includes the MAC ID of each device, the I/O connections  
it supports, and the input/output lengths for those I/O connections.  
In most cases, the vendor of each DeviceNet device provides this  
information, but if not, NI-DNET provides a tool that helps you determine  
this information. Searching a DeviceNet network to determine information  
about connected devices is often referred to as a network who, and thus the  
NI-DNET tool is called SimpleWho. This tool is not a complete network  
management or configuration tool. It provides read-only information about  
the DeviceNet devices connected to your National Instruments DeviceNet  
interface.  
To launch SimpleWho, right-click the DeviceNet interface (such as  
DNET0) in MAX, and select SimpleWho.  
For more information on the SimpleWho tool, refer to the NI-DNET help  
file in MAX. This help file can be opened using the Help button in the  
SimpleWho tool itself.  
NI-DNET Objects  
The NI-DNET software, like the DeviceNet Specification, uses  
object-oriented concepts to represent components in the DeviceNet system  
(for more information about object-oriented concepts in the DeviceNet  
Specification, refer to Appendix A, DeviceNet Overview). However,  
whereas in the DeviceNet Specification objects represent a multitude of  
components in DeviceNet devices, NI-DNET objects represent  
components of the Windows device driver software. The NI-DNET device  
driver objects do not correspond directly to objects contained in remote  
devices. To facilitate access to the DeviceNet network, the NI-DNET  
objects provide a more concise representation of various objects defined in  
the DeviceNet Specification.  
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Much like any other object-oriented system, NI-DNET device driver  
objects use the concepts of class, instance, attribute, and service to describe  
their features. The NI-DNET device driver software provides three classes  
of objects: Interface Objects, Explicit Messaging Objects, and I/O Objects.  
You can open an instance of an NI-DNET object using one of the three  
open functions (ncOpenDnetExplMsg, ncOpenDnetIntf, or  
ncOpenDnetIO). The services for an NI-DNET object are accomplished  
using the NI-DNET functions, which can be called directly from your  
programming environment (such as Microsoft C/C++ or LabVIEW). The  
essential attributes of an NI-DNET object are initialized using its open  
function; you can access other attributes using ncGetDriverAttror  
ncSetDriverAttr. The attributes of NI-DNET device driver objects are  
called driver attributes, to differentiate them from actual attributes in  
remote DeviceNet devices.  
For complete information on each NI-DNET object, including its driver  
attributes and supported functions (services), refer to your NI-DNET  
Programmer Reference Manual.  
Interface Object  
The Interface Object represents a DeviceNet interface (physical DeviceNet  
port on your DeviceNet board). Since this interface acts as a device on the  
DeviceNet network much like any other device, it is configured with its  
own MAC ID and baud rate.  
Use the Interface Object to do the following:  
Configure NI-DNET settings that apply to the entire interface  
Start and stop communication for all NI-DNET objects associated with  
the interface  
Explicit Messaging Object  
The Explicit Messaging Object represents an explicit messaging  
connection to a remote DeviceNet device (physical device attached to your  
interface by a DeviceNet cable). Since only one explicit messaging  
connection is created for a given device, the Explicit Messaging Object is  
also used for features that apply to the device as a whole.  
Use the Explicit Messaging Object to do the following:  
Execute the DeviceNet Get Attribute Single service on the remote  
device (ncGetDnetAttribute)  
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Execute the DeviceNet Set Attribute Single service on the remote  
device (ncSetDnetAttribute)  
Send any other explicit message request to the remote device and  
receive the associated explicit message response  
(ncWriteDnetExplMsg, ncReadDnetExplMsg)  
Configure NI-DNET settings that apply to the entire remote device  
I/O Object  
The I/O Object represents an I/O connection to a remote DeviceNet device  
(physical device attached to your interface by a DeviceNet cable). The  
I/O Object usually represents I/O communication as a master with a remote  
slave device, but it can also be used for I/O communication as a slave.  
The I/O Object supports as many master/slave I/O connections as currently  
allowed by the DeviceNet Specification. This means that you can use  
polled, strobed, and COS/cyclic I/O connections simultaneously for a given  
device. As specified by the DeviceNet Specification, only one master/slave  
I/O connection of a given type can be used for each device (MAC ID). For  
example, you cannot open two polled I/O connections for the same device.  
Use the I/O Object to do the following:  
Read data from the most recent message received on the  
I/O connection (ncReadDnetIO)  
Write data for the next message produced on the I/O connection  
(ncWriteDnetIO)  
Example  
Figure 1-2 shows an example of how NI-DNET objects can be used to  
communicate on a DeviceNet network. This example shows three  
DeviceNet devices. The first device (at MAC ID 1) is the National  
Instruments DeviceNet interface. The second device (at MAC ID 5) uses  
NI-DNET to access a polled and a COS I/O connection simultaneously.  
The third device (at MAC ID 8) uses NI-DNET to access an explicit  
messaging connection and a strobed I/O connection.  
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Access to device at  
MAC ID 5  
Access to device at  
MAC ID 8  
I/O Object  
Device MAC ID = 5  
Connection Type = COS Connection Type = Poll  
I/O Object  
Device MAC ID = 5  
Explicit Messaging  
Object  
Device MAC ID = 8  
I/O Object  
Device MAC ID = 8  
Connection Type = Strobe  
Your National Instruments  
DeviceNet Interface  
Interface Object  
Interface MAC ID = 1  
Baud Rate = 500K  
Figure 1-2. NI-DNET Objects for a Network of Three Devices  
Using NI-CAN with NI-DNET  
Controller Area Network (CAN) is the low-level protocol used for  
DeviceNet communications. In addition to the NI-DNET functions, your  
National Instruments DeviceNet hardware can also be used for low-level  
access to CAN messages using the NI-CAN software. NI-CAN is intended  
primarily for applications that require direct access to CAN messages, such  
as test applications for automotive (non-DeviceNet) networks. When  
connecting to a DeviceNet network, the NI-CAN capabilities are useful for  
the following applications:  
Low-level monitoring of CAN messages to determine conformance to  
DeviceNet specifications  
Implementation of sections of the DeviceNet Specification yourself,  
such as custom configuration tools  
can be used with the same CAN card. The general rule is that each CAN  
card can only be used for one API at a time.  
Use of NI-DNET is restricted to port 1 (top port) of Series 1 CAN cards.  
For more information on hardware provided in CAN kits, refer to  
Chapter 2, NI-DNET Hardware Overview.  
You can view each CAN card in MAX with either DeviceNet or CAN  
features. To change the view of a CAN card in MAX, right-click the card  
and select Protocol. In this dialog you can select either DeviceNet for  
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NI-DNET (default), or CAN for NI-CAN. When the CAN protocol is  
selected, you can access CAN tools in MAX, such as the Bus Monitor tool  
that displays CAN messages in their raw form.  
In order to develop NI-CAN applications, you must install NI-CAN  
components such as documentation and examples. The NI-CAN software  
components are available within the NI-DNET installer.  
Launch the setup.exeprogram for the NI-DNET installer in the same  
manner as your original installation (CD or ni.comdownload). Within  
the installer, select both NI-DNET and NI-CAN components in the  
feature tree.  
When you right-click a port in MAX and select Properties, the resulting  
Interface selection uses the syntax CANxor DNETxbased on your protocol  
selection. Regardless of which protocol is selected, the number x is the only  
relevant identifier with respect to NI-CAN and NI-DNET functions. For  
example, if you select DNET0 as an interface in MAX, you can run an  
NI-DNET application that uses DNET0, then you can run an NI-CAN  
application that uses CAN0. Both applications refer to the same port,  
and can run at different times, but not simultaneously.  
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NI-DNET Hardware Overview  
Types of Hardware  
The National Instruments DeviceNet hardware includes the PCI-CAN,  
PXI-8461, and PCMCIA-CAN.  
The PCI-CAN is software configurable and compliant with the PCI Local  
Bus Specification. It features the National Instruments MITE bus interface  
chip that connects the card to the PCI I/O bus. With a PCI-CAN, you can  
make your PC-compatible computer with PCI Local Bus slots  
communicate with and control DeviceNet devices.  
The PXI-8461 is software configurable and compliant with the PXI  
Specification and CompactPCI Specification. It features the National  
Instruments MITE bus interface chip that connects the card to the PXI or  
CompactPCI I/O bus. With a PXI-8461 card, you can make your PXI or  
CompactPCI chassis communicate with and control DeviceNet devices.  
PCMCIA-CAN hardware is a 16-bit, Type II PC Card that is software  
configurable and compliant with the PCMCIA standards for 16-bit PC  
cards. With a PCMCIA-CAN card, you can make your PC-compatible  
notebook with PCMCIA slots communicate with and control DeviceNet  
devices.  
The PCI-CAN, PXI-8461, or PCMCIA-CAN in your DeviceNet kit is fully  
compliant with the DeviceNet Specification.  
All of the DeviceNet hardware uses the Intel 386EX embedded processor  
to implement time-critical features provided by the NI-DNET software.  
The cards communicate with the NI-DNET driver through on-board shared  
memory and an interrupt.  
The DeviceNet physical communication link protocol is based on the  
Controller Area Network (CAN) protocol. The physical layers of the  
PCI-CAN, PXI-8461, and PCMCIA-CAN fully conform to the DeviceNet  
physical layer requirements. The physical layer is optically isolated to  
500 V and is powered from the DeviceNet bus power supply. DeviceNet  
interfacing is accomplished using the Intel 82527 CAN controller chip.  
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For more information on the DeviceNet physical layer and cables used to  
connect to your DeviceNet devices, refer to Appendix B, Cabling  
Requirements.  
For connection to the network, the PCI-CAN, PXI-8461, and  
PCMCIA-CAN for DeviceNet provide combicon-style pluggable screw  
terminals, as required by the DeviceNet Specification.  
Differences Between CAN Kits and DeviceNet Kits  
National Instruments provides hardware/software kits for both CAN and  
DeviceNet. Since the CAN kits apply to a broad range of applications such  
as automotive testing, the hardware in those kits offers a wide variety of  
options. To ensure that the hardware product operates properly on a  
DeviceNet network, we recommend that you purchase DeviceNet kits only.  
The card provided in your DeviceNet kit can be used with both NI-DNET  
and NI-CAN software.  
Hardware in CAN kits is referenced as Series 2. Hardware in DeviceNet  
kits is referenced as Series 1. Series 2 CAN cards cannot be used with the  
NI-DNET software (NI-CAN only). The features of Series 2 CAN cards are  
specifically designed for CAN applications, and provide no distinct  
advantages for DeviceNet. For more information on Series 2 hardware,  
refer to the hardware overview in the NI-CAN Hardware and Software  
Manual.  
Hardware in CAN kits offers 1-port and 2-port variants. NI-DNET operates  
on one port only. If you use NI-DNET on a 2-port Series 1 CAN card, only  
the top port can be used.  
Hardware in CAN kits offer special transceivers (physical layer) such as  
Low-Speed/Fault-Tolerant (LS) and Single-Wire (SW). Hardware in CAN  
kits also offer the option to power the transceiver from the card, not the  
network. These transceivers cannot be used with DeviceNet. Only  
High-Speed (HS) transceivers comply with the DeviceNet specification.  
Hardware in CAN kits use the DB-9 D-SUB connector. Hardware in  
DeviceNet kits use the combicon-style connector from the DeviceNet  
specification.  
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3
Developing Your Application  
This chapter explains how to develop an application using the NI-DNET  
functions.  
Accessing NI-DNET from your Programming  
Environment  
Applications can access the NI-DNET driver software by using either  
LabVIEW, LabWindows/CVI, Microsoft Visual C/C++, Borland  
C/C++, or Visual Basic. If you are using any other development  
environment, you must access the DNET library directly. Each of these  
language interface techniques is summarized below.  
LabVIEW  
For applications written in LabVIEW, NI-DNET provides a complete  
function library, front panel controls, and examples.  
NI-DNET functions and controls are available in the LabVIEW palettes. In  
LabVIEW 7.1 or later, the NI-DNET palette is located within the top-level  
NI Measurements palette. In earlier LabVIEW versions, the NI-DNET  
palette is located at the top-level.  
The reference for each NI-DNET function is provided in the NI-DNET  
Programmer Reference Manual. To access the reference for a function  
from within LabVIEW, press <Ctrl-H> to open the help window, click on  
the NI-DNET function, and then follow the link.  
The NI-DNET software includes a full set of examples for LabVIEW.  
These examples teach basic NI-DNET programming as well as advanced  
topics. The example help describes each example and includes a link you  
can use to open the VI. The NI-DNET example help is in Help»Find  
Examples»Hardware Input and Output»DeviceNet.  
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LabWindows/CVI  
Within LabWindows/CVI, the NI-DNET function panel is located in  
Library»NI-DNET. Like other LabWindows/CVI function panels, the  
NI-DNET function panel provides help for each function and the ability to  
generate code.  
The reference for each NI-DNET function is provided in the NI-DNET  
Programmer Reference Manual. You can access reference for each  
function directly from within the function panel.  
The header file for NI-DNET is nidnet.h. The library for NI-DNET is  
nidnet.lib.  
The NI-DNET software includes a full set of examples for  
LabWindows/CVI. The NI-DNET examples are installed in the  
LabWindows/CVI directory under samples\nidnet. Each example  
provides a complete LabWindows/CVI project (.prjfile). A description  
of each example is provided in comments at the top of the .cfile.  
When you compile your LabWindows/CVI application for NI-DNET,  
it is automatically linked with nidnet.lib, the link library for  
LabWindows/CVI. When NI-DNET is installed, the installation program  
checks to see which compatible C compiler you are using with  
LabWindows/CVI (Microsoft or Borland), and copies an appropriate  
nidnet.libfor that compiler.  
Microsoft Visual Basic  
To create an NI-DNET application in Visual Basic, add the nidnet.bas  
file to your project. This allows you to call any NI-DNET function file from  
your code.  
The nidnet.basfile is located in the MS Visual Basicfolder of the  
NI-DNETfolder. The typical path to this folder is \Program Files\  
National Instruments\NI-DNET\MS Visual Basic.  
The reference for each NI-DNET function is provided in the NI-DNET  
Programmer Reference Manual, which you can open from Start»All  
Programs»National Instruments»NI-DNET.  
You can find examples for Visual Basic in the examplessubfolder of the  
MS Visual Basicfolder. Each example is in a separate folder. A .vbp  
file with the same name as the example opens the Visual Basic project. A  
description of the example is located in a Help form within the project.  
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Microsoft C/C++  
The NI-DNET software supports Microsoft Visual C/C++ version 6.  
The header file and library for Visual C/C++ 6 are in the MS Visual C  
folder of the NI-DNETfolder. The typical path to this folder is \Program  
Files\National Instruments\NI-DNET\MS Visual C. To use  
NI-DNET, include the nidnet.hheader file in your code, then link with  
the nidnetms.liblibrary file.  
For C applications (files with a.cextension), include the header file by  
adding a #includeto the beginning of your code, as in:  
#include "nidnet.h"  
For C++ applications (files with .cppextension), define _cplusplus  
before including the header, such as:  
#define _cplusplus  
#include "nidnet.h"  
The _cplusplusdefine enables the transition from C++ to the C language  
NI-DNET functions.  
The reference for each NI-DNET function is provided in the NI-DNET  
Programmer Reference Manual, which you can open from Start»All  
Programs»National Instruments»NI-DNET. You can find examples for  
Visual C++ in the examplessubfolder of the MS Visual Cfolder. Each  
example is in a separate folder. A .cfile with the same name as the  
example contains a description the example in comments at the top of the  
code. At the command prompt, after setting MSVC environment variables  
(such as with MS vcvars32.bat), you can build each example using a  
command such as:  
cl –I.. singin.c ..\nidnetms.lib  
Borland C/C++  
The NI-DNET software supports Borland C/C++ version 5 or later.  
The header file and library for Borland C/C++ are in the Borland C folder  
of the NI-DNET folder. The typical path to this folder is \Program  
Files\National Instruments\NI-DNET\Borland C.  
To use NI-DNET, include the nidnet.hheader file in your code, then link  
with the nidnetbo.liblibrary file.  
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For C applications (files with .cextension), include the header file by  
adding a #includeto the beginning of your code, like this:  
#include "nidnet.h"  
For C++ applications (files with .cppextension), define _cplusplus  
before including the header, such as:  
#define _cplusplus  
#include "nidnet.h"  
The _cplusplusdefine enables the transition from C++ to the C language  
NI-DNET functions.  
The reference for each NI-DNET function is provided in the NI-DNET  
Programmer Reference Manual, which you can open from Start»All  
Programs»National Instruments»NI-DNET.  
You can find examples for Visual C++ in the examplessubfolder of the  
Borland C folder. Each example is in a separate folder. A .cfile with the  
same name as the example contains a description the example in comments  
at the top of the code.  
Other Programming Languages  
You can directly access NI-DNET from any programming environment  
that allows you to request addresses of functions that a dynamic link library  
(DLL) exports. The functions used to access a DLL in this manner are  
provided by the Microsoft Win32 functions of Windows. Using these  
Microsoft Win32 functions to access a DLL is often referred to as direct  
entry. To use direct entry with NI-DNET, complete the following steps:  
1. Load the NI-DNET DLL, nican.dll.  
The following C language code fragment illustrates how to call the  
Win32 LoadLibraryfunction and check for an error.  
#include <windows.h>  
#include "nidnet.h"  
HINSTANCE NidnetLib = NULL;  
NidnetLib=LoadLibrary("nican.dll");  
if (NidnetLib == NULL) {  
return FALSE; /*Error*/  
}
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2. Get the addresses for the NI-DNET DLL functions you will use.  
Your application must use the Win32 GetProcAddressfunction to  
get the addresses of the NI-DNET functions your application needs.  
For each NI-DNET function used by your application, you must define  
a direct entry prototype. For the prototypes for each function exported  
by nican.dll, refer to the NI-DNET Programmer Reference Manual.  
The following code fragment illustrates how to get the addresses of the  
ncOpenDnetIO, ncCloseObject, and ncReadDnetIOfunctions.  
static NCTYPE_STATUS (_NCFUNC_ *PncOpenDnetIO)  
(NCTYPE_STRING ObjName,  
NCTYPE_OBJH_P ObjHandlePtr);  
static NCTYPE_STATUS (_NCFUNC_ *PncCloseObject)  
(NCTYPE_OBJH ObjHandle);  
static NCTYPE_STATUS (_NCFUNC_ *PncReadDnetIO)  
(NCTYPE_OBJH ObjHandle, NCTYPE_UINT32 SizeofData,  
NCTYPE_ANY_P Data);  
PncOpenDnetIO = (NCTYPE_STATUS (_NCFUNC_ *)  
(NCTYPE_STRING, NCTYPE_OBJH_P))  
GetProcAddress(NidnetLib,  
(LPCSTR)"ncOpenDnetIO");  
PncCloseObject = (NCTYPE_STATUS (_NCFUNC_ *)  
(NCTYPE_OBJH))  
GetProcAddress(NidnetLib,  
(LPCSTR)"ncCloseObject");  
PncRead = (NCTYPE_STATUS (_NCFUNC_ *)  
(NCTYPE_OBJH, NCTYPE_UINT32, NCTYPE_ANY_P))  
GetProcAddress(NidnetLib,  
(LPCSTR)"ncReadDnetIO");  
If GetProcAddressfails, it returns a NULL pointer. The following  
code fragment illustrates how to verify that none of the calls to  
GetProcAddressfailed.  
if ((PncOpenDnetIO == NULL) ||  
(PncCloseObject == NULL) ||  
(PncReadDnetIO == NULL)) {  
FreeLibrary(NidnetLib);  
printf("GetProcAddress failed");  
}
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3. Configure your application to de-reference the pointer to call an  
NI-DNET function, as illustrated by the following code.  
NCTYPE_STATUS status;  
NCTYPE_OBJH MyObjh;  
status = (*PncOpenDnetIO) ("DNET0", &MyObjh);  
if (status < 0) {  
printf("ncOpenDnetIO failed");  
}
4. Free nican.dll.  
Before exiting your application, you need to free nican.dllwith the  
following command.  
FreeLibrary(NidnetLib);  
Programming Model for NI-DNET Applications  
The following steps provide an overview of how to use the NI-DNET  
functions in your application. The steps are shown in Figure 3-1 in  
flowchart form. The NI-DNET functions are described in detail in the  
NI-DNET Programmer Reference Manual.  
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Start  
1. Open Interface object  
2. Open all I/O and Explicit Messaging (EM)  
objects required for your application  
3. Call ncSetDriverAttr, if needed  
Start communication  
Your DeviceNet Application:  
• Write output data  
• Wait for available input data  
• Read input data  
• Get or Set DeviceNet Attribute  
• Open/Close any new I/O or EM  
connection if the interface PollMode  
is not equal to NC_POLL_AUTO  
No  
Finished?  
Yes  
Stop communication  
1. Close I/O and EM objects.  
2. Close the Interface object.  
End  
Figure 3-1. General Programming Steps for an NI-DNET Application  
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Step 1. Open Objects  
Before you use an NI-DNET object in your application, you must configure  
and open it using either ncOpenDnetIntf, ncOpenDnetExplMsg, or  
ncOpenDnetIO. These open functions return a handle for use in all  
subsequent NI-DNET calls for that object.  
The ncOpenDnetIntffunction configures and opens an Interface Object.  
Your NI-DNET application uses this Interface Object to start and stop  
communication. The Interface Object must be the first NI-DNET object  
opened by your application.  
The ncOpenDnetExplMsgfunction configures and opens an Explicit  
Messaging Object, and the ncOpenDnetIOfunction configures and opens  
an I/O Object.  
Step 2. Start Communication  
Start communication to initialize DeviceNet connections to remote  
devices. Use the Interface Object to call the ncOperateDnetIntf  
function with the Opcodeparameter set to Start.  
The following optional steps can be done before you start communication:  
For an I/O Object, if it is not acceptable to send output data of all zeros,  
call ncWriteDnetIOto provide valid output values for the initial  
transmission.  
For an I/O Object, if your application is multitasking, call the  
ncCreateNotificationor ncCreateOccurrencefunction with  
the DesiredStateparameter set to Read Available. This notifies  
your application when new input data is received from the remote  
device.  
For any NI-DNET object, if any of the Driver attributes needs to be  
changed, call ncSetDriverAttrwith the attribute Id and attribute  
value. The ncSetDriverAttrfunction cannot be called after the  
communication has started.  
Step 3. Run Your DeviceNet Application  
After you open your NI-DNET objects and start communication, you are  
ready to interact with the DeviceNet network.  
Complete the following steps with an I/O Object:  
1. Call the ncWriteDnetIOfunction to write output data for subsequent  
transmission on the DeviceNet network.  
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2. Call the ncWaitForStatefunction with the DesiredState  
parameter set to Read Available. This function waits for output  
data to be transmitted and for new input data to be received. If your  
application is multitasking, you might have other tasks to do in your  
application while you wait for new input data. If so, use the  
ncCreateNotificationor ncCreateOccurrencefunction  
instead of ncWaitForState(refer to Step 2. Start Communication).  
3. Call the ncReadDnetIOfunction to read input data received from the  
DeviceNet network.  
4. Loop back to step 1 as needed.  
Complete the following steps with an Explicit Messaging Object:  
1. Call the ncWaitForStatefunction with the DesiredState  
parameter set to Established. This ensures that the explicit message  
connection is established before you send the first explicit message  
request.  
2. To get an attribute from a remote DeviceNet device, call the  
ncGetDnetAttributefunction.  
3. To set the value of an attribute in a remote DeviceNet device, call the  
ncSetDnetAttributefunction.  
4. To invoke other explicit message services in a remote DeviceNet  
device, use the ncWriteDnetExplMsgfunction to write the service  
request, the ncWaitForStatefunction to wait for the service  
response, and the ncReadDnetExplMsgfunction to read the service  
response.  
5. Loop back to step 2 as needed.  
Addition of Slave Connections after  
Communication Start  
If you need to add I/O and Explicit Messaging connections after the  
communication on the network has started, you can call  
ncOpenDnetExplMsgand ncOpenDnetIOas long as the Interface  
Object’s poll mode had been configured to NC_POLL_SCAN(Scanned) or  
NC_POLL_INDIV(Individual). Since the Automatic poll mode  
(NC_POLL_AUTO) calculates the expected packet rate (EPR) based on the  
estimated network bandwidth, all the I/O connections have to be opened  
before you start the communication if the Automatic mode is selected. The  
EPR restrictions due to different values of the PollModeparameter still  
apply to the I/O objects. For details on these requirements, refer to  
ncOpenDnetIOand ncOpenDnetIntffunction descriptions in the  
NI-DNET Programmer Reference Manual.  
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Step 4. Stop Communication  
Before you exit your application, stop communication to shut down  
DeviceNet connections to remote devices. Use the Interface Object to  
call the ncOperateDnetIntffunction with the Opcodeparameter set  
to Stop.  
Step 5. Close Objects  
Before you exit your application, close all NI-DNET objects using the  
ncCloseObjectfunction.  
Multiple Applications on the Same Interface  
The NI-DNET software allows multiple NI-DNET applications to use the  
same interface object simultaneously, as long as the interface configuration  
remains the same. For example, you can run both the SingleDevice  
example and SimpleWho on DNET0 as long as the Interface MacId,  
BaudRate, and PollModeparameters are the same in both applications  
(SimpleWho uses a PollModeof Scanned). Similarly, you can open up  
two copies of the SingleDeviceexample and communicate with two  
different devices as if it were through a single application. These same rules  
apply to the I/O Object and the Explicit Messaging Object.  
As long as all the configuration attributes are the same, any object can be  
opened multiple times. You can enable only one notification or wait  
(through ncWaitForState, ncCreateNotification, or  
ncCreateOccurrencefunctions) for an object, no matter how many  
handles you have opened for that particular object. For example, if you are  
running two copies of the SingleDeviceexample on the same interface  
with the same connection types, the notification triggers in only one  
application at a time.  
The synchronization of events and the protection of the object I/O data is  
the responsibility of the application developer. Similarly, the application  
performance might change based on the number of objects open and the  
frequency of API calls made in each application. For example, several calls  
to ncGetDnetAttributein one application might slow down another  
application running on the same interface.  
To ensure proper clean up of all the objects, each open call to an object  
should be matched by a close call to the same object, and each call to  
ncOperateDnetIntf with NC_OP_STARTcode should be matched by  
a call to the same function with NC_OP_STOPcode.  
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If you use two different applications on the same interface and open I/O  
connections to different devices, you must set PollModeto either  
Scannedor Individual. You cannot use PollModeof Automatic,  
because that requires all I/O connections to be open prior to the first start  
of communication.  
Checking Status in LabVIEW  
For applications written in LabVIEW, status checking is handled  
automatically. For all NI-DNET functions, the lower left and right  
terminals provide status information using LabVIEW Error Clusters.  
LabVIEW Error Clusters are designed so that status information flows  
from one function to the next, and function execution stops when an error  
occurs. For more information, refer to the Error Handling section in the  
LabVIEW online reference.  
Within your LabVIEW block diagram, you wire the Error inand  
Error outterminals of NI-DNET functions together in succession.  
When an error is detected in an NI-DNET function (statusfield true),  
all NI-DNET functions wired together are skipped except for  
ncCloseObject. The ncCloseObjectfunction executes regardless  
of whether an error occurred, thus ensuring that all NI-DNET objects are  
closed properly when execution stops due to an error. Depending on how  
you want to handle errors, you can wire the Error inand Error out  
terminals together per-object (group a single open/close pair), per-device  
(group together Explicit Messaging and I/O Objects for a given device), or  
per-network (group all functions for a given interface).  
As with any other LabVIEW error cluster, you can view error descriptions  
using built-in LabVIEW features such as Explain Error in the Help menu,  
or the Simple Error Handler VI in your diagram.  
Checking Status in C, C++, and Visual Basic  
Each C language NI-DNET function returns a value that indicates the status  
of the function call. This status value is zero for success, greater than zero  
for a warning, and less than zero for an error.  
After every call to an NI-DNET function, your program should check to see  
if the return status is nonzero. If so, call the ncStatusToStringfunction  
to obtain an ASCII string which describes the error/warning. You can then  
use standard C function, such as printf, to display this ASCII string.  
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Your application code should check the status returned from every  
NI-DNET function. If an error is detected, you should close all NI-DNET  
handles, then exit the application. If a warning is detected, you can display  
a message for debugging purposes, or simply ignore the warning.  
For more information on status checking, refer to the ncStatusToString  
function in the NI-DNET Programmer Reference Manual.  
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4
NI-DNET Programming  
Techniques  
This chapter describes various techniques to help you program your  
NI-DNET application. The techniques include configuration of  
I/O connection timing, using I/O data (assemblies), using explicit  
messaging, and handling multiple devices.  
This section provides information on how I/O connections relate to one  
another and how your configuration of I/O connection timing can affect the  
overall performance of your DeviceNet system. The various types of  
I/O connections provided by DeviceNet are described in Chapter 1,  
NI-DNET Software Overview.  
In a master/slave DeviceNet I/O system, the master determines the timing  
of all I/O communication. Within your NI-DNET application, the  
ncOpenDnetIOfunction configures the timing for I/O connections in  
which your application communicates as master. As you read this section,  
you might want to refer to the description of the ncOpenDnetIOfunction  
in the NI-DNET Programmer Reference Manual.  
Expected Packet Rate  
Each DeviceNet I/O connection contains an attribute called the expected  
packet rate, which specifies the expected rate (in milliseconds) of messages  
(packets) for the I/O connection. For NI-DNET, you use the  
ExpPacketRateparameter of the ncOpenDnetIOfunction to configure  
the expected packet rate.  
After you start communication, the embedded microprocessor on your  
National Instruments DeviceNet interface transmits messages at the  
ExpPacketRate. This means that after the I/O connection is configured,  
your NI-DNET application does not need to be concerned with the timing  
of messages on the DeviceNet network.  
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When you select an ExpPacketRatefor an I/O connection, you must  
consider all I/O connections in your system. For example, although you  
might be able to configure an ExpPacketRateof 3 ms for a single  
I/O connection, you cannot configure a 3 ms ExpPacketRatefor 40 I/O  
connections because DeviceNet’s bandwidth capabilities cannot support  
40 messages in a 3 ms time frame.  
The following sections describe how to evaluate system considerations so  
that you can configure valid values for ExpPacketRate.  
Strobed I/O  
For strobed I/O connections, the master broadcasts a single strobe  
command message to all strobed slaves. Since all strobed I/O connections  
transfer data at the rate of this single strobe command message, the  
ExpPacketRateof each strobed I/O connection must be set to the  
same value.  
The common ExpPacketRatefor all strobed I/O connections should  
provide enough time for the strobe command and each strobed slave’s  
response. You must also allow time for other I/O messages and explicit  
messages to occur in the ExpPacketRatetime frame. If you do not know  
the time needed, let NI-DNET calculate a safe value for you (refer to the  
section Automatic EPR Feature later in this chapter).  
Figure 4-1 shows a timing example for four strobed devices at MAC ID 9,  
11, 12, and 13. Notice that since MAC ID 11 is slow to respond, the  
ExpPacketRateis set to 20 ms to provide additional safety margin for  
other messages.  
0 ms  
5 ms  
10 ms  
15 ms  
20 ms  
Figure 4-1. Strobed I/O Timing Example  
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Polled I/O  
Polled I/O connections use a separate poll command and response message  
for each device.  
The overall scheme that NI-DNET uses to time polled I/O connections is  
determined by the PollModeparameter of ncOpenDnetIntf. This  
PollModeparameter applies to all polled I/O connections (all calls to  
ncOpenDnetIOwith ConnectionTypeof Poll).  
The following sections describe different schemes you can use for  
polled I/O.  
Scanned Polling  
You can set the ExpPacketRateof each polled I/O connection to the same  
value used for all strobed I/O. Using a common ExpPacketRatefor all  
strobed and polled I/O is referred to as scanned I/O. Scanned I/O is also  
referred to as scanned polling with respect to polled I/O connections. When  
you use scanned I/O, NI-DNET transmits all strobe and poll command  
messages onto the network in quick succession.  
Scanned I/O is a simple, efficient way to handle I/O connections that  
require similar response rates. With scanned I/O, the master knows that all  
strobe and poll commands go out at the same time. Therefore, the master  
does not need to manage individual timers, thus optimizing processing  
overhead. Scanned I/O also provides overall consistency. If a given  
DeviceNet system uses only scanned I/O, you know that all higher level  
control algorithms can execute at the single common strobe/poll  
ExpPacketRate.  
The common ExpPacketRatefor all strobed and polled I/O connections  
should provide enough time for all strobe/poll commands and each slave’s  
response. You must also allow time for other I/O messages and explicit  
messages to occur in the ExpPacketRatetime frame.  
NI-DNET provides two different methods you can use to configure  
scanned I/O:  
If you set the PollModeparameter of ncOpenDnetIntfto  
Automatic, NI-DNET automatically calculates a valid common  
ExpPacketRatevalue for each strobed and polled I/O connection.  
When you use this scheme, you do not need to specify a valid  
ExpPacketRatewhen you open your strobed/polled I/O connections.  
For more information, refer to the Automatic EPR Feature section later  
in this chapter.  
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If you set the PollModeparameter of ncOpenDnetIntfto Scanned,  
to configure scanned I/O you must specify the exact same  
ExpPacketRatewhen you open each of your strobed/polled  
I/O connections. Using this scheme, you must determine a valid  
ExpPacketRatefor your DeviceNet system.  
Figure 4-2 shows a scanned polling example for four polled devices at  
MAC ID 14, 17, 20, and 30. The shaded areas indicate other message  
traffic, such as the strobed I/O messages shown in Figure 4-1.  
0 ms  
5 ms  
10 ms  
15 ms  
20 ms  
Figure 4-2. Scanned Polling Timing Example  
Background Polling  
Scanned polling can be less efficient when used with devices with  
significantly different response times or devices with significantly different  
rates of physical measurement. In the example above (Figure 4-2), consider  
what would happen if device 14 took 52 ms to respond and device 20 took  
38 ms to respond. In this case, even though device 17 and device 30  
respond well within 20 ms, the common ExpPacketRatewould need to  
be at least 52 ms. This situation can often be avoided using a special case  
of scanned polling called background polling.  
To configure background polling, you first set the PollModeparameter of  
ncOpenDnetIntfto Scanned. Then for each polled I/O connection you  
configure (ncOpenDnetIOwith ConnectionTypeset to Poll), you must  
set ExpPacketRateto either a foreground rate or a background rate. The  
foreground poll rate is the same as the common ExpPacketRateused for  
all strobed I/O. Devices in this group generally respond quickly to poll  
commands or have data that changes relatively quickly. The background  
poll rate must be an exact multiple of the foreground poll rate. Devices in  
this group generally respond slowly to poll commands or have data that  
changes relatively slowly (such as temperature).  
Background polling provides many of the same advantages as scanned  
polling. The handling of only two groups optimizes performance. Also,  
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background polling maintains overall network consistency because  
NI-DNET evenly disperses all background poll commands among multiple  
foreground cycles. In other words, all background poll commands are not  
sent in quick succession and thus do not generate quick bursts of traffic on  
the network.  
Figure 4-3 shows a background polling example which resolves the  
problem discussed previously. Devices at MAC ID 17 and 30 are  
foreground polled every 20 ms (as before). Devices at MAC ID 14 and 20  
are background polled every 60 ms (3 times the 20 ms foreground rate).  
The shaded areas indicate other message traffic.  
0 ms  
20 ms  
40 ms  
60 ms  
Figure 4-3. Background Polling Timing Example  
Individual Polling  
When the underlying response rates of all polled I/O devices do not fit into  
two clear groups, background polling can still be inefficient. For example,  
assume you have four different polled I/O sensors capable of updating  
measured input at 10 ms, 35 ms, 100 ms, and 700 ms respectively. Each  
device responds to its poll command within 1 ms but measures data at a  
different rate (such as a pushbutton for 10 ms and a temperature sensor for  
700 ms). You could group these into a foreground rate of 10 ms and a  
background rate of 700 ms, but then much DeviceNet bandwidth would be  
wasted polling the 35 ms and 100 ms devices at the foreground rate. For  
this situation, the individual polling scheme is most appropriate.  
To configure individual polling, first set the PollModeparameter of  
ncOpenDnetIntfto Individual. Then for each polled I/O connection  
you configure (ncOpenDnetIOwith ConnectionTypeset to Poll), you  
must set ExpPacketRateto the rate desired for that device. Unlike the  
scanned polling or background polling scheme, each poll command is no  
longer associated with the strobe command’s rate, but instead is solely  
based on its ExpPacketRate.  
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Since the poll commands are not synchronized for individual polling, they  
can often be scattered relatively randomly. They can be evenly interspersed  
for a while, then suddenly occur in bursts of back-to-back messages.  
Because of this inconsistency, you should use smaller MAC IDs for smaller  
ExpPacketRatevalues. Since smaller MAC IDs in DeviceNet usually  
gain access to the network before larger MAC IDs, this helps to ensure that  
smaller rates can be maintained during bursts of increased traffic.  
Figure 4-4 shows an individual polling example: MAC ID 3 is polled  
every 10 ms, MAC ID 10 every 35 ms, MAC ID 12 every 100 ms, and  
MAC ID 13 every 700 ms. Only the poll commands are shown (not poll  
responses or other messages).  
0 ms  
20 ms  
40 ms  
60 ms  
80 ms  
Figure 4-4. Individual Polling Timing Example  
Cyclic I/O  
Cyclic I/O connections essentially use the same timing scheme as  
individually polled I/O connections. Each cyclic I/O connection sends its  
data at the configured ExpPacketRate. The main difference is that  
cyclic I/O data is transferred from slave to master, rather than from master  
to slave.  
In the DeviceNet Specification, a poll command message is exactly the  
same as a cyclic output message (master to slave data). Since cyclic data  
from master to slave can be handled using individual polling, cyclic I/O  
connections are more commonly used for input data from slave to master.  
For NI-DNET, this means that for cyclic I/O connections, ncOpenDnetIO  
is normally called with InputLengthnonzero and OutputLengthzero.  
Just as for individually polled I/O, you should use smaller MAC IDs for  
smaller cyclic I/O ExpPacketRatevalues. Doing so ensures that cyclic  
I/O traffic is prioritized properly.  
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Change-of-State (COS) I/O  
Change-of-State I/O connections use the same timing scheme as cyclic I/O  
connections, but in addition to the ExpPacketRate, COS I/O sends data  
to the master whenever a change is detected.  
For COS I/O, the cyclic transmission is used solely to verify that the  
I/O connection still exists, so the ExpPacketRateis typically set to a large  
value, such as 10,000 (10 seconds). Given such a large ExpPacketRate,  
the main performance concerns for COS I/O are an appropriate MAC ID,  
and if needed, a nonzero InhibitTimer.  
In many cases, a given COS I/O device cannot detect data changes very  
quickly. If a COS device is capable of detecting quickly changing data,  
there is a chance that it could transmit many COS messages back-to-back,  
precluding other I/O messages and thus dramatically impairing overall  
DeviceNet performance. This problem is demonstrated in Figure 4-5.  
Back to Back  
COS I/O Data  
Changing Frequently  
Some of the  
Other I/O May  
Have Timed Out  
COS I/O  
0 ms  
5 ms  
10 ms  
15 ms  
20 ms  
Figure 4-5. Congestion Due to Back-to-Back COS I/O  
This problem can be prevented if you increase the MAC ID of the  
frequently changing COS I/O device. If the COS device has a higher  
MAC ID than other devices, it cannot preclude their I/O messages.  
You can also prevent back-to-back COS I/O messages if you set the  
InhibitTimerdriver attribute using ncSetDriverAttr. After  
transmitting COS data, the I/O connection must wait InhibitTimer  
before it can transmit COS data again. A reasonable value for  
InhibitTimerwould be the smallest ExpPacketRateof an  
I/O connection with a larger MAC ID than the COS I/O device.  
Automatic EPR Feature  
For cyclic I/O connections, a valid ExpPacketRateis required for  
your call to ncOpenDnetIO. For COS I/O connections, a nonzero  
ExpPacketRateis recommended for your call to ncOpenDnetIObut  
can be set to a large value.  
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For strobed and polled I/O connections, determination of a valid  
ExpPacketRatecan be somewhat complex. If you have trouble  
estimating an ExpPacketRatevalue for strobed/polled I/O, set the  
PollModeparameter of your initial call to ncOpenDnetIntfto  
Automatic. When you use this automatic EPR feature, the  
ExpPacketRateparameter of ncOpenDnetIOis ignored for  
strobed/polled I/O (ConnectionTypeof Strobeor Poll), and NI-DNET  
calculates a safe EPR value for you. This automatic EPR is the same for all  
strobed and polled I/O connections (scanned I/O).  
After you start communication, you can use the ncGetDriverAttr  
function to determine the value calculated for ExpPacketRate. From that  
value, you can then experiment with other ExpPacketRateconfigurations  
using PollModeof Scannedor Individual.  
The following information is used by NI-DNET to calculate a safe EPR:  
NI-DNET assumes that it is the only master in your DeviceNet system.  
The BaudRateparameter of ncOpenDnetIntfdetermines the time  
taken for each message.  
The InputLengthand OutputLengthparameters of each  
ncOpenDnetIOdetermine the time needed for each I/O message.  
NI-DNET assumes that each strobed/polled I/O device can respond to  
its command within 2 ms.  
NI-DNET sets aside a fixed amount of time for explicit messages. This  
time depends on the baud rate.  
Using I/O Data in Your Application  
Appendix A, DeviceNet Overview, explains that the data transferred to and  
from a DeviceNet device on an I/O connection is usually processed by an  
Assembly Object within the slave device. Input assemblies represent the  
data received by NI-DNET from a remote device, and output assemblies  
represent data that NI-DNET transmits to a remote device.  
To use a device’s I/O data within your application, you need to understand  
the contents of its input and output assemblies. You can find this  
information in the following places:  
Printed documentation provided by the device’s vendor.  
If the device conforms to a standard device profile, the I/O assemblies  
are defined within the DeviceNet Specification.  
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Some device vendors provide comments about I/O assemblies in an  
Electronic Data Sheet (EDS). The EDS file is a text file whose format  
is defined by the DeviceNet Specification.  
Ask the device’s vendor if they have filled out a DeviceNet  
compliance statement. This form is located at the front of the  
DeviceNet Specification, and it provides information about the device,  
including its I/O assemblies.  
After you open an NI-DNET I/O Object and start communication, you use  
the ncWriteDnetIOfunction to write an output assembly for a device and  
the ncReadDnetIOfunction to read an input assembly received from a  
remote device. Both of these functions access the entire assembly as an  
array of bytes.  
In most cases, the array of bytes for an input or output assembly contains  
more than one value. In DeviceNet terminology, an individual data value  
within an I/O assembly is referred to as a member.  
Documentation for the members of an input or output assembly includes  
the position of each member in the assembly (often shown as a table with  
byte/bit offsets) and a listing of the attribute in the device that each member  
represents (often shown as class, instance, and attribute identifiers). For  
standard device profiles, the I/O assemblies are documented in the device  
profile’s specification, and the actual attributes are documented in the  
individual object specifications. Attribute documentation includes the  
attribute’s DeviceNet data type and a complete explanation of its meaning.  
As an example of I/O assembly documentation, consider the standard  
AC Drive device profile. For this device profile, the DeviceNet  
Specification defines an output assembly called Basic Speed Control  
Output (Assembly Object instance 20). This output assembly is used to  
start/stop forward motion at a given speed and to reset faults in the device.  
The bytes of this output assembly are shown in Figure 4-6, and the attribute  
mapping is shown in Table 4-1.  
Byte  
Bit 7  
Bit 6  
Bit 5  
Bit 4  
Bit 3  
Bit 2  
Fault Reset  
0
Bit 1  
Bit 0  
Run Fwd  
0
0
1
2
3
0
0
0
0
0
0
0
0
0
0
0
0
Speed Reference (Low Byte)  
Speed Reference (High Byte)  
Figure 4-6. AC Drive Output Assembly, Instance 20  
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Table 4-1. Attribute Mapping for Basic Speed Control Output Assembly  
Member  
Name  
Class  
Name  
Attribute  
Name  
Class ID  
Instance ID  
Attribute ID  
Run Fwd  
Control  
29 hex  
1
Run1  
3
Supervisor  
Fault  
Reset  
Control  
Supervisor  
29 hex  
2A hex  
1
1
FaultRst  
SpeedRef  
12  
8
Speed  
Reference  
AC/DC  
Drive  
By consulting the specifications for the Control Supervisor object and the  
AC/DC Drive object, you can determine that the DeviceNet data type for  
Run Fwd and Fault Reset is BOOL(boolean), and the DeviceNet data type  
for Speed Reference is INT(16-bit signed integer).  
Accessing I/O Members in LabVIEW  
Many fundamental differences exist between the encoding of a DeviceNet  
data type and its equivalent data type in LabVIEW. For example, for a  
32-bit integer, the DeviceNet DINTdata type uses Intel byte ordering  
(lowest byte first), and the equivalent LabVIEW I32data type uses  
Motorola byte ordering (highest byte first).  
To make it easier for you to avoid these data type issues in your  
LabVIEW application, NI-DNET provides two functions to convert  
between LabVIEW data types and DeviceNet data types:  
ncConvertForDnetWriteand ncConvertFromDnetRead. These  
functions are used to access individual members of an I/O assembly using  
normal LabVIEW controls and indicators.  
The following steps show an example of how you can use  
ncConvertForDnetWriteto access the Basic Speed Control Output  
Assembly described in the previous section:  
1. Use the NI-DNET palette to place ncConvertForDnetWriteinto  
your diagram.  
2. Right-click on the DnetData interminal and select Create  
Constant, then initialize the first 4 bytes of the array to zero.  
3. Right-click on the DnetTypeterminal and select Create Constant,  
then select BOOLfrom the enumeration.  
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4. Right-click on the ByteOffsetterminal and select Create Constant,  
then enter 0as the byte offset.  
5. Right-click on the 8[TF]interminal and select Create Control. In  
the front panel control that appears, you can use the button at index 0  
to control Run Fwd and the button at index 2 to control Fault Reset.  
6. Using the NI-DNET palette, place ncConvertForDnetWriteinto  
your diagram.  
7. Wire the DnetData outterminal from the previous Convertinto the  
DnetData interminal of this Convert.  
8. Right-click on the DnetTypeterminal and select Create Constant,  
then select INTfrom the enumeration.  
9. Right-click on the ByteOffsetterminal and select Create Constant,  
then enter 2as the byte offset.  
10. Right-click on the I32/I16/I8 interminal and select Create  
Control. You can use the front panel control that appears to change  
Speed Reference.  
11. Using the NI-DNET palette, place ncWriteDnetIOinto your  
diagram.  
12. Wire the DnetData outterminal from the previous Convertinto the  
Dataterminal of ncWriteDnetIO.  
For more information on the ncConvertForDnetWriteand  
ncConvertFromDnetReadfunctions, refer to the NI-DNET Programmer  
Reference Manual. For information on LabVIEW data types and their  
equivalent DeviceNet data types, refer to Chapter 1, NI-DNET Data Types,  
in the NI-DNET Programmer Reference Manual.  
Accessing I/O Members in C  
Since DeviceNet data types are very similar to C language data types,  
individual I/O members can be accessed in a straightforward manner. You  
can use the standard C language pointer manipulations to convert between  
C language data types and DeviceNet data types.  
The following steps show an example of how standard C language can be  
used to access the Basic Speed Control Output Assembly described in the  
previous section.  
1. Declare an array of 4 bytes, as in the following.  
NCTYPE_UINT8OutputAsm[4];  
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2. Initialize the array to all zero.  
for (I = 0; I < 4; I++)  
OutputAsm [I] = 0;  
3. Assume you have two boolean variables, RunFwdand ResetFault,  
of type NCTYPE_BOOL. For LabWindows/CVI, these variables could  
be accessed from front panel buttons. The following code inserts these  
boolean variables into OutputAsm.  
if (RunFwd)  
OutputAsm [0] |= 0x01;  
if (FaultReset)  
OutputAsm [0] |= 0x04;  
4. Assume you have an integer variable SpeedRefof type  
NCTYPE_INT16. For LabWindows/CVI, this variable could be  
accessed from a front panel control. The following code inserts this  
integer variable into OutputAsm.  
*(NCTYPE_INT16 *)(&( OutputAsm[2])) = SpeedRef;  
5. Write the output assembly to the remote device.  
status = ncWriteDnetIO(objh, sizeof(OutputAsm),  
OutputAsm);  
For information on NI-DNET’s C language data types and their equivalent  
DeviceNet data types, refer to Chapter 1, NI-DNET Data Types, of the  
NI-DNET Programmer Reference Manual.  
Using Explicit Messaging Services  
The NI-DNET Explicit Messaging Object represents an explicit messaging  
connection to a remote DeviceNet device. You use ncOpenDnetExplMsg  
to configure and open an NI-DNET Explicit Messaging Object.  
The following sections describe how to use the Explicit Messaging Object.  
Get and Set Attributes in a Remote DeviceNet Device  
The two most commonly used DeviceNet explicit messages are the Get  
Attribute Single service and the Set Attribute Single service. These services  
are used to get or set the value of an attribute contained in a remote device.  
The easiest way to execute the Get Attribute Single service on a remote  
device is to use the NI-DNET ncGetDnetAttributefunction. The  
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easiest way to execute the Set Attribute Single service on a remote device  
is to use the NI-DNET ncSetDnetAttributefunction.  
For a given attribute of a DeviceNet device, you need the following  
information to use the ncGetDnetAttributeor ncSetDnetAttribute  
function:  
The class and instance identifiers for the object in which the attribute  
is located  
The attribute identifier  
The attribute’s DeviceNet data type  
You can normally find this information from the object specifications  
contained in the DeviceNet Specification, but many DeviceNet device  
vendors also provide this information in the device’s documentation.  
For the C programming language, the attribute’s DeviceNet data type  
determines the corresponding NI-DNET data type you use to declare a  
variable for the attribute’s value. For example, if the attribute’s DeviceNet  
data type is INT(16-bit signed integer), you should declare a C language  
variable of type NCTYPE_INT16, then pass the address of that variable as  
the Attrparameter of the ncGetDnetAttributeor  
ncSetDnetAttributefunction.  
For LabVIEW, the attribute’s DeviceNet data type determines  
the corresponding LabVIEW data type to use with the  
ncConvertFromDnetReadfunction converts a DeviceNet attribute read  
using ncGetDnetAttributeinto an appropriate LabVIEW data type. The  
ncConvertForDnetWritefunction converts a LabVIEW data type into an  
appropriate DeviceNet attribute to write using ncSetDnetAttribute. For  
more information on these LabVIEW conversion functions, refer to the  
Using I/O Data in Your Application section.  
Other Explicit Messaging Services  
To execute services other than Get Attribute Single and Set Attribute Single,  
use the following sequence of function calls: ncWriteDnetExplMsg  
ncWaitForState ncReadDnetExplMsg. The ncWriteDnetExplMsg  
,
,
function sends an explicit message request to a remote DeviceNet device.  
The ncWaitForStatefunction waits for the explicit message response,  
and the ncReadDnetExplMsgfunction reads that response.  
Use ncWriteDnetExplMsgfor such DeviceNet services as Reset, Save,  
Restore, Get Attributes All, and Set Attributes All. Although the DeviceNet  
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Specification defines the overall format of these services, in most cases  
their meaning and service data are object-specific or vendor-specific.  
Unless your device requires such services and documents them in detail,  
you probably do not need them for your application.  
You need the following information to use the ncWriteDnetExplMsgand  
ncReadDnetExplMsgfunctions for a given explicit messaging service:  
The class and instance identifiers for the object to which the service  
will be directed.  
The service code used to identify the service.  
The length and format of service request and response data. Some of  
data formats are defined by the service’s overall specification (such as  
in Appendix G, DeviceNet Explicit Services, in the DeviceNet  
Specification manual), but many data formats are object-specific or  
vendor-specific. For example, for the Reset service, Appendix G  
defines the service’s code for use with any object, but its actual data  
format is defined in the specification for the Identity Object.  
The error codes that can be returned in the service response. Error  
codes that are common to all services can be found in Appendix H,  
DeviceNet Error Codes, in the DeviceNet Specification manual, but  
many error codes are specific to the service, object, or vendor.  
As with the ncGetDnetAttributeand ncSetDnetAttribute  
functions, the service data formats for the request and response are  
specified in terms of DeviceNet data types. These DeviceNet data types are  
converted to/from the data types of your programming environment (C or  
LabVIEW) as discussed in previous sections.  
Handling Multiple Devices  
This section describes techniques you can use to efficiently implement an  
application that communicates with a large number of DeviceNet devices.  
In such an application, there might be only one call to ncOpenDnetIntf  
(only one network), but there are usually multiple calls to ncOpenDnetIO  
(and possibly ncOpenDnetExplMsg).  
Configuration  
If the configuration parameters used with ncOpenDnetIOtend to change  
over time, you might want to organize them in data structures instead of  
using constants.  
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For the C programming language, you can declare a structure typedefto  
store the parameters of ncOpenDnetIO, similar to the following:  
typedef struct {  
NCTYPE_UINT32DeviceMacId;  
NCTYPE_CONN_TYPEConnectionType;  
NCTYPE_UINT32InputLength;  
NCTYPE_UINT32OutputLength;  
NCTYPE_UINT32ExpPacketRate;  
} OpenDnetIO_Struct;  
For LabVIEW, a cluster that contains these parameters is already defined  
for use with ncOpenDnetIO.  
You can use this structure/cluster to declare an array that contains one entry  
for each call you make to ncOpenDnetIO. In LabVIEW and  
LabWindows/CVI, you can use front panel controls to index through this  
array and update configurations as needed.  
In your code, write a For loop to index through the array and call  
ncOpenDnetIOonce for each array entry. This simplifies your code  
because it does not contain a long list of sequential open calls, but instead  
all open calls are combined into a concise loop.  
Object Handles  
If you use an array to store configuration parameters for ncOpenDnetIO  
,
you can use this same scheme to store the ObjHandlereturned by  
ncOpenDnetIO. Within the For loop used for ncOpenDnetIO, you can store  
the resulting ObjHandleinto an array of object handles. Throughout your  
code, you can index into this array to obtain the appropriate object handle.  
Using an array of object handles is particularly useful in the LabVIEW  
programming environment because it eliminates confusing routing of  
individual object handle wires.  
For applications with only a few object handles, another useful technique  
for LabVIEW is to store each object handle in an indicator, then create a  
local variable for each call that uses the handle. To create the indicator,  
right-click on the ObjHandle outterminal and select Create Indicator.  
To create a local variable, right-click on the indicator, select Create»Local  
Variable, right-click on the local variable, and select Change To Read  
Local. For more information on local variables, refer to the LabVIEW  
online reference.  
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Main Loop  
If your application essentially accesses all DeviceNet input/output data as  
a single image, you would normally wait for read data to become available  
on one of the input connections (such as a strobed I/O connection), read all  
input data, execute your application code, then write all output data. The  
wait is important because it helps to synchronize your application with the  
overall DeviceNet network traffic.  
In single-loop applications such as this, you normally set the PollMode  
parameter of ncOpenDnetIntfto Automaticor Scannedso that all poll  
command messages are sent out in quick succession.  
Within a single-loop application, error handling is often done for the entire  
application as a whole. In the C programming language, this means that  
when an error is detected with any NI-DNET object, you display the error  
and exit the application. In LabVIEW, this means that you wire all error  
clusters of NI-DNET VIs together.  
If your application uses different control code for different DeviceNet  
devices, you might want to split your application into multiple tasks. You  
can easily write a multitasking application by creating a notification for the  
NI-DNET Read Availstate. This notification occurs when either input  
data is available (to synchronize your code with each device’s  
I/O messages), or an error occurs. In the C programming language, you  
create this notification callback using the ncCreateNotification  
function. In LabVIEW, you create this notification callback using the  
ncCreateOccurrencefunction.  
In multiple-loop applications such as this, you normally set the PollMode  
parameter of ncOpenDnetIntfto Individualso that each poll  
command message can be sent out at its own individual rate.  
Within a multiple-loop application, error handling is done separately for  
each task. In the C programming language, this means that when an error  
is detected, you handle it for the appropriate task, but you do not exit the  
application. In LabVIEW, this means that you only wire the error clusters  
of NI-DNET VIs that apply to each task, and thus you write different  
sub-diagrams that are not wired together in any way.  
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DeviceNet Overview  
This appendix gives an overview of DeviceNet.  
History of DeviceNet  
The Controller Area Network (CAN) was developed in the early 1980s by  
Bosch, a leading automotive equipment supplier. CAN was developed to  
overcome the limitations of conventional automotive wiring harnesses.  
CAN connects devices such as engine controllers, anti-lock brake  
controllers, and various sensors and actuators on a common serial bus.  
By using a common pair of signal wires, any device on a CAN network can  
communicate with any other device.  
As CAN implementations became widespread throughout the automotive  
industry, CAN was standardized internationally as ISO 11898, and major  
semiconductor manufacturers such as Intel, Motorola, and Philips began  
producing CAN chips. With these developments, many manufacturers of  
industrial automation equipment began to consider other applications of  
CAN technology. Automotive and industrial device networks showed  
many similarities, including the transition away from dedicated signal  
lines, low cost, resistance to harsh environments, and excellent real-time  
capabilities.  
In response to these similarities, Allen-Bradley developed DeviceNet, an  
industrial networking protocol based on CAN. DeviceNet built on CAN’s  
communication facilities to provide higher-level features which allow  
industrial devices from different vendors to operate on the same network.  
Soon after DeviceNet was developed, Allen-Bradley transferred the  
specification to an independent organization called the Open DeviceNet  
Vendor’s Association (ODVA). ODVA formally manages the DeviceNet  
Specification and provides services to facilitate development of DeviceNet  
devices and tools by various vendors. Due in large part to the efforts of  
ODVA, hundreds of different vendors now provide DeviceNet products for  
a wide range of applications.  
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Appendix A  
DeviceNet Overview  
Physical Characteristics of DeviceNet  
The following list summarizes the physical characteristics of DeviceNet.  
Trunkline-dropline cabling—main trunk cable with a drop cable for  
each device  
Selectable baud rates of 125 K, 250 K, and 500 K  
Table A-1. DeviceNet Baud Rates and Wiring Lengths  
Baud  
Rate  
Trunk  
Length  
Drop Length  
Maximum  
Drop Length  
Cumulative  
125 Kb/s 500 m (1640 ft)  
250 Kb/s 250 m (820 ft)  
500 Kb/s 100 m (328 ft)  
6 m (20 ft)  
6 m (20 ft)  
6 m (20 ft)  
156 m (512 ft)  
78 m (256 ft)  
39 m (128 ft)  
Support for up to 64 devices—each device identifies itself using a  
MAC ID (Media Access Control Identifier) from 0–63  
Device removal/insertion without severing the network  
Simultaneous support for both network-powered and self-powered  
devices  
Various connector styles  
For complete information on how to connect your National Instruments  
hardware onto the DeviceNet network, refer to your getting started manual.  
General Object Modeling Concepts  
The DeviceNet Specification uses object-oriented modeling to describe the  
behavior of different components in a device, how those components relate  
to one another, and how network communication takes place. The  
following paragraphs briefly describe object-oriented modeling and how  
these concepts are used within the DeviceNet Specification.  
In object-oriented terminology, a classification of components with similar  
qualities is called a class. For example, different classes of geometric  
shapes could include squares, circles, and triangles. Figure A-1 shows  
various classes and instances of geometric shapes.  
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1
2
3
4
1
2
3
1
2
Class Square  
Class Triangle  
Class Circle  
Figure A-1. Classes of Geometric Shapes  
All squares belong to the same class because they all have similar qualities,  
such as four equal sides. The term instance refers to a specific instance of  
a given class. For example, a blue square of four inches per side would be  
one instance of the class square, and a red square of five inches per side  
would be another instance. The term object is often used as a synonym for  
the term instance, although in some contexts it might also refer to a class.  
Each class defines a set of attributes which represent its externally visible  
characteristics. The set of attributes defined by a class is common to all  
instances within that class. For the class square, attributes could include  
length of each side and color. For the class circle, attributes could include  
radius and color. Each class also defines a set of services (or methods)  
which is used to perform an operation on an instance. For the class square,  
services could include resize, rotate, or change color.  
Object Modeling in the DeviceNet Specification  
Figure A-2 illustrates the object modeling used within the DeviceNet  
Specification.  
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Application  
Object(s)  
Parameter  
Object  
Identity  
Object  
Assembly  
Object  
Message  
Router  
Explicit  
Messaging  
I/O  
DeviceNet  
Object  
Connection  
Objects  
DeviceNet Network  
Figure A-2. Object Modeling Used in DeviceNet Specification  
Every DeviceNet device contains at least one instance (instance one) of the  
Identity Object. The Identity Object instance defines attributes which  
describe the device, including the device’s vendor, product name, and  
serial number. The Identity Object also defines services which apply to the  
entire device. For example, if you use the Reset service on instance one of  
the Identity Object, the device resets to its power on state.  
Another class of object contained in every DeviceNet device is the  
Connection Object. Each instance of the Connection Object represents a  
communication path to one or more devices. Attributes of each Connection  
Object instance include the maximum number of bytes produced on the  
connection, the maximum number of bytes consumed, and the expected  
rate at which data is transferred.  
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In Figure A-2, the term Application Object(s) refers to objects within the  
device which are used to perform its fundamental behavior. For example,  
within a photoelectric sensor, an instance of the Presence Sensing object  
(an Application Object) represents the physical photoelectric sensor  
hardware. Within a position controller device, an instance of the Position  
Controller object (an Application Object) is provided for every axis (motor)  
which can be controlled using the device.  
For more information on the classes, instances, attributes, and services  
provided by DeviceNet, refer to the DeviceNet Specification. You can find  
additional information on the specific classes and instances supported by a  
given device in the documentation that came with the device.  
Although the NI-DNET driver software provides object instances which  
are used to access the DeviceNet network, these objects do not correspond  
directly to the objects defined by the DeviceNet Specification, and the  
NI-DNET functions do not directly correspond to the services defined by  
DeviceNet. To facilitate access to your DeviceNet network, the features  
provided by the NI-DNET driver are a simplification of the objects and  
services defined in the DeviceNet Specification.  
Explicit Messaging Connections  
Each device on the DeviceNet network supports at least one explicit  
messaging connection. Explicit messaging connections provide a  
general-purpose communication path used to execute services on a  
particular object in a device.  
For a given explicit messaging connection between two DeviceNet devices,  
the device requesting execution of the service is called the client, and the  
device to which the service request is directed is called the server. Your  
NI-DNET software can be used as an explicit messaging client with any  
number of DeviceNet server devices.  
Using an explicit messaging connection, the client device sends an explicit  
message request to the server device. This request indicates the service to  
perform and the object to which the service is directed. When the server  
receives the explicit message request, it executes the service and sends an  
explicit message response to the client device. If the service executed  
successfully, this response contains information requested by the client.  
The MAC ID (address) of the explicit message client and server is  
contained in the header of the DeviceNet explicit messages.  
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Appendix A  
DeviceNet Overview  
The following tables describe the general format of DeviceNet explicit  
message requests and responses as they appear on the DeviceNet network.  
Table A-2. Explicit Message Request  
Field  
Description  
Service Code  
This number identifies the service requested by the client.  
The DeviceNet Specification defines valid service codes.  
Class ID  
This number identifies the class to which the service is directed.  
The DeviceNet Specification defines valid class IDs.  
Instance ID  
This number identifies the instance to which the service is directed. If  
the instance ID is zero, the service is directed to the entire class. If the  
instance ID is one or greater, the service is directed to a specific instance  
within the class.  
Service Data  
Data bytes specific to the Service Code. The number and format of these  
data bytes is defined by the specification for the service.  
Table A-3. Explicit Message Response  
Field  
Description  
Service Code  
This number indicates success or failure for execution of the service. If  
this number is the same as the Service Code of the request, the service  
executed successfully. If this number is 14 hex, the service failed to  
execute due to an error.  
Service Data  
If the service executed successfully, this field contains data bytes which  
are specific to the Service Code. The number and format of these data  
bytes are defined by the specification for the service.  
If the service failed to execute, the first byte of Service Data contains  
a General Error Code which describes the error, and the second byte  
contains an Additional Error Code which qualifies the error. The  
DeviceNet Specification defines valid values for the General Error Code  
and Additional Error Code.  
The DeviceNet Specification defines a set of services supported in a  
common way by different devices. These common services include Reset,  
Save, Restore, Get Attribute Single, and Set Attribute Single.  
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The Get Attribute Single service obtains the value of a specific attribute  
within a device’s object, and the Set Attribute Single service sets the value  
of an attribute. These Get and Set services are the most commonly used  
explicit messaging services. Since these two services are used often,  
NI-DNET provides functions for these services: ncGetDnetAttribute  
and ncSetDnetAttribute.  
Other services defined by DeviceNet are used less often. For these services,  
NI-DNET provides general purpose functions to send an explicit message  
request (ncWriteDnetExplMsg) and receive an explicit message  
response (ncReadDnetExplMsg). These NI-DNET functions use  
parameters which are similar to the explicit message request/response  
listed above. For more information on DeviceNet common services other  
than Get/Set Attribute Single, refer to the DeviceNet Specification.  
I/O Connections  
In addition to explicit messaging connections, DeviceNet devices provide  
another type of Connection Object called an I/O connection.  
I/O connections provide a communication path for the exchange of  
physical input/output (sensor/actuator) data as well as other  
control-oriented data. I/O connections are useful for transferring data at  
regular intervals.  
Since many DeviceNet devices do not begin their normal operation until an  
I/O connection is established, explicit messaging is often used for  
configuration and initialization. For example, for a device with an analog  
input, the I/O connection is normally used to read the analog input  
measurement, and explicit messages are used for configuration such as  
setting the measurement range and units (such as –10 to +10 V versus  
4 to 20 mA).  
The DeviceNet Specification defines two types of I/O connections:  
master/slave and peer-to-peer. In master/slave I/O connections, a master  
device uses an I/O connection to communicate with one or more slave  
devices, and those slave devices can only communicate with the master and  
not one another. In peer-to-peer I/O connections, each device on the  
network can communicate as a peer, and communication paths between  
peer devices are established as needed. The NI-DNET software currently  
supports only master/slave I/O connections because the procedure used to  
establish these I/O connections is more well defined. For this reason,  
almost all existing DeviceNet devices only implement master/slave  
I/O connections.  
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Appendix A  
DeviceNet Overview  
The DeviceNet Specification defines four types of master/slave  
I/O connections: polled, bit strobed, change-of-state (COS), and cyclic.  
A slave device can support at most one polled, one strobed, and one COS  
or cyclic connection (COS and cyclic connections cannot be used  
simultaneously).  
Polled I/O  
The polled I/O connection uses a request/response scheme for each device.  
The master sends a poll command (request) message to the slave device  
with any amount of output data. The slave then sends a poll response  
message back to the master with any amount of input data. The poll  
command/response messages are handled individually for each slave which  
supports polled I/O connections. Polled I/O is typically used for devices  
which provide both input and output data, such as position controllers and  
modular I/O devices.  
Figure A-3 shows an example of four polled slave devices.  
Output data  
Input data  
Master  
MAC ID = 1  
12 Byte Poll Command  
15 Byte Poll Response  
5 Byte Poll Command  
6 Byte Poll Response  
2 Byte Poll  
Command  
5 Byte Poll  
Response  
20 Byte Poll  
Command  
3 Byte Poll  
Response  
Slave  
MAC ID = 9  
Slave  
MAC ID = 11  
Slave  
MAC ID = 12  
Slave  
MAC ID = 13  
Figure A-3. Polled I/O Example  
Bit Strobed I/O  
The (bit) strobed I/O connection is designed to move small amounts of  
input data from the slave to its master. Strobed I/O is typically used for  
simple sensors, such as photoelectric sensors and limit switches.  
Strobed I/O is also called bit strobed I/O since the master sends a 64-bit  
(8-byte) message containing a single bit of output data for each strobed  
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slave. This strobe command (request) message is received by all slave  
devices simultaneously and can be used to trigger simultaneous  
measurements (such as to take multiple photoelectric readings  
simultaneously).  
When a strobed slave receives the strobe command, it uses the output data  
bit that corresponds to its own MAC ID (for example, the slave with  
MAC ID 5 uses bit 5). Regardless of the value of its output bit, each  
strobed slave responds to the command message by sending an individual  
strobe message back to the master. The slave’s strobe response contains  
from 0 to 8 bytes of input data.  
Figure A-4 shows an example of four strobed slave devices.  
Output data  
Input data  
Master  
MAC ID = 1  
4 Byte Strobe Response  
1 Byte Strobe Response  
2 Byte Strobe  
6 Byte Strobe  
Response  
Response  
Slave  
MAC ID = 9  
Slave  
MAC ID = 11  
Slave  
MAC ID = 12  
Slave  
MAC ID = 13  
8 Byte Strobe Command  
9 10 11 12 13  
0
1
2
61 62 63  
Used  
by 9  
Used  
by 12  
Used Used  
by 11 by 13  
Figure A-4. Strobed I/O Example  
Change-of-State and Cyclic I/O  
The change-of-state (COS) and cyclic I/O connections both use the same  
underlying communication mechanisms. Both transmit data at a fixed  
interval called the expected packet rate (EPR). Since COS and cyclic  
I/O connections use the same messaging on the DeviceNet network, they  
are often referred to as a single I/O connection called COS/cyclic I/O.  
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DeviceNet Overview  
The cyclic I/O connection enables a slave device to send input data to its  
master at the configured EPR interval. You normally configure the EPR to  
be consistent with the rate at which the device measures its physical input  
sensors. For example, if a temperature sensor can take a measurement at  
most once every 500 ms, you would configure the cyclic I/O connection’s  
EPR as 500 ms. Cyclic I/O can be configured to send output data from  
master to slave, but this configuration is seldom used since it is essentially  
the same as polled I/O. Cyclic I/O messages can contain any amount  
of data.  
The COS I/O connection enables a slave device to send input data to its  
master when a change is detected on its physical inputs. In addition to  
sending input data when a change is detected, the COS slave also sends its  
input data at a slower EPR interval that lets the master know it is still  
functioning. COS I/O is typically used for devices with physical inputs that  
can change frequently but can have the same input value for a long time.  
For example, if a pushbutton device supports COS I/O, you might  
configure its EPR as 3 seconds since the device sends a message  
immediately if a button is pressed. COS I/O can be configured to send  
output data from master to slave. Although master-to-slave COS output is  
seldom used, it can be useful for things like front-panel pushbuttons which  
are sent to a slave’s discrete outputs (such as LEDs and simple motors).  
COS I/O messages can contain any amount of data.  
When using COS/cyclic I/O connections, you can configure the device that  
receives data to send an acknowledgment so that the transmitting device  
can verify that the data was received successfully. For example, if you  
configure slave-to-master COS I/O (input length nonzero), the master  
sends an acknowledgment to the slave each time it receives an input  
message. Since the acknowledgment message is used for verification only,  
it does not contain data. If this verification can be handled using other  
means (such as using strobed I/O to verify device status), the  
acknowledgment message can be suppressed. For information on how to  
suppress COS/cyclic acknowledgments using NI-DNET, refer to the  
description of the I/O Object in the NI-DNET Programmer Reference  
Manual.  
Since COS and cyclic I/O use the same messages on the DeviceNet  
network, they cannot be used simultaneously for a given slave device.  
Also, polled I/O uses the same messages on the DeviceNet network as  
master-to-slave output messages of COS/cyclic I/O. This means that a slave  
device can use slave-to-master COS/cyclic I/O simultaneously with  
polled I/O, but not master-to-slave COS/cyclic I/O.  
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Figure A-5 shows an example of four COS/cyclic I/O connections.  
Output data  
Input data  
Master  
MAC ID = 1  
2 Byte Cyclic to Master  
COS ACK to Slave  
EPR = 500 ms, no ACK  
4 Byte COS to Master  
EPR = 200 ms  
Cyclic ACK  
to Master  
6 Byte COS  
to Slave  
EPR = 400 ms,  
no ACK  
12 Byte Cyclic  
to Slave  
EPR = 100 ms  
Slave  
Slave  
Slave  
Slave  
MAC ID = 9  
MAC ID = 11  
MAC ID = 12  
MAC ID = 13  
Figure A-5. COS/Cyclic I/O Example  
Assembly Objects  
One of the more important objects in the DeviceNet Specification is the  
Assembly Object. There are two types of Assembly Object: input  
assemblies and output assemblies. Assembly objects act like a switchboard,  
routing incoming and outgoing data to its proper location within the device.  
Output assemblies receive an output message from an I/O connection and  
distribute its contents to multiple attributes within the slave. Input  
assemblies gather multiple attributes within the slave for transmission on  
an I/O connection.  
Figure A-6 shows the operation of input and output assemblies.  
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Instance  
Attributes  
Instance  
Attributes  
Instance  
Attributes  
Output Assembly, Associated  
with an Output Message  
Such as a Poll Command  
Input Assembly, Associated  
with an Input Message  
Such as a Poll Response  
Figure A-6. Input and Output Assemblies  
As a more specific example, consider a DeviceNet photoelectric sensor  
(photoeye) or a limit switch. These devices contain a single instance of a  
class called the Presence Sensing object. This instance has attributes for the  
Output Signal (on/off) and Diagnostic Status (good/fault). These two  
attributes are often routed through a single input assembly consisting of a  
single byte.  
Figure A-7 shows an example of a Presence Sensing instance and its input  
assembly.  
Presence Sensor Instance 1  
Attributes  
Output, BOOL  
On Delay, UINT  
Off Delay, UINT  
Diagnostic, BOOL  
Operate Mode, BOOL  
0
7
0
6
0
5
0
4
0
3
0
2
Bit  
1
0
One byte input assembly,  
often returned as a strobe  
response or COS input message.  
Figure A-7. Input Assembly for Photoeye or Limit Switch  
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As you can see, to use the data bytes contained in I/O messages, it is  
important to know the format of a device’s internal input and output  
assemblies.  
Device Profiles  
To provide interoperability for devices of the same type, the DeviceNet  
Specification defines various device profiles. The goal behind device  
profiles is that for a given type of device, such as a photoelectric sensor, it  
should be relatively straightforward to replace a sensor from one vendor  
with a sensor from another vendor.  
All devices which conform to a given profile must do the following:  
Exhibit the same behavior  
Use the same object model (certain instances are required)  
Contain the same input and output assemblies  
Contain the same set of configurable attributes  
In addition to required features, most device profiles define a variety of  
optional features. When an optional feature is supported by a vendor, it  
must be supported as defined by the DeviceNet Specification. Device  
profiles also allow for vendor-specific features.  
The DeviceNet Specification provides device profiles for such devices as  
photoelectric sensors, limit switches, motor starters, position controllers,  
and mass-flow controllers.  
Open DeviceNet Vendors Association (ODVA)  
This chapter provides only a short summary of DeviceNet. For additional  
information, such as a list of DeviceNet products and how to purchase the  
DeviceNet Specification, refer to the ODVA Web site at www.odva.org.  
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B
Cabling Requirements  
This appendix describes the cabling requirements for the hardware.  
Cables should be constructed to meet these requirements as well as the  
requirements of DeviceNet. DeviceNet cabling requirements can be found  
in the DeviceNet Specification.  
Connector Pinouts  
The PCI-CAN, PXI-8461, and the PCMCIA-CAN bus-powered cable each  
have a Combicon-style pluggable screw terminal connector. The  
PCMCIA-CAN bus-powered cable also has a DB-9 D-SUB connector.  
The 5-pin Combicon-style pluggable screw terminal follows the pinout  
required by the DeviceNet Specification. Figure B-1 shows the pinout for  
this connector.  
2
1
4
3
5
1
2
V+  
CAN_H  
3
4
Shield  
CAN_L  
5
V–  
CAN_H and CAN_L are signal lines that carry the data on the DeviceNet  
network. These signals should be connected using twisted-pair cable.  
The V+ and V– signals supply power to the DeviceNet physical layer. Refer  
to the Power Supply Information for the DeviceNet Ports section for more  
information.  
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Appendix B  
Cabling Requirements  
Figure B-2 shows the end of a PCMCIA-CAN bus-powered cable. The  
arrow points to pin 1 of the 5-pin screw terminal block. All of the signals  
on the 5-pin Combicon-style pluggable screw terminal are connected  
directly to the corresponding pins on the 9-pin D-SUB following the pinout  
in Figure B-3.  
V-  
C_L  
SH  
C_H  
V+  
J2  
J1  
Figure B-2. PCMCIA-CAN Bus-Powered Cable  
The 9-pin D-SUB follows the pinout recommended by CiA Draft  
Standard 102. Figure B-3 shows the pinout for this connector.  
No Connection  
Optional Ground (V–)  
CAN_L  
CAN_H  
V–  
No Connection  
No Connection  
V+  
Shield  
Figure B-3. Pinout for 9-Pin D-SUB Connector  
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Cabling Requirements  
Power Supply Information for the DeviceNet Ports  
The bus must supply power to each DeviceNet port. The bus power supply  
should be a DC power supply with an output of 10 V to 30 V. The  
DeviceNet physical layer is powered from the bus using the V+ and V–  
lines.  
The power requirements for the DeviceNet port are shown in Table B-1.  
You should take these requirements into account when determining the  
requirements of the bus power supply for the system.  
Table B-1. Power Requirements for the DeviceNet Physical Layer  
for Bus-Powered Versions  
Characteristic  
Voltage Requirement  
Current Requirement  
Specification  
V+ 10 to 30 VDC  
40 mA typical  
100 mA maximum  
For the PCI-CAN, a jumper controls the source of power for the DeviceNet  
physical layer. The location of this jumper is shown in Figure B-4.  
1
2
3
4
1
2
Power Supply Jumper J6  
Product Name  
3
4
Serial Number  
Assembly Number  
Figure B-4. PCI-CAN Power Source Jumper  
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The PCI-CAN is shipped with this jumper set in the EXT position. In this  
position, the physical layer is powered from the bus (the V+ and V– pins  
on the Combicon connector). The jumper must be in this position for the  
DeviceNet interface to be compliant with the DeviceNet Specification.  
If the DeviceNet interface is being used in a system where bus power is not  
available, the jumper may be set in the INT position. In this position, the  
physical layer is powered by the host computer or internally. The physical  
layer is still optically isolated. Figure B-5 shows how to configure your  
jumpers for internal or external power supplies.  
INT  
3
EXT  
INT  
3
EXT  
1
2
1
2
a. Internal Power Mode  
(DeviceNet)  
Figure B-5. Power Source Jumpers  
For port one of the PXI-8461, power is configured with jumper J5. The  
location of these jumper is shown in Figure B-6.  
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3
4
2
1
5
1
2
Power Supply Jumper J6  
Power Supply Jumper J5  
3
4
Assembly Number  
Product Name  
5
Serial Number  
Figure B-6. PXI-8461 Parts Locator Diagram  
Connecting pins 1 and 2 of a jumper configures the PXI-8461 physical  
layer to be powered externally (from the bus cable power). In this  
configuration, the power must be supplied on the V+ and V– pins on the  
port connector. The jumper must be in this position for the DeviceNet  
interface to be compliant with the DeviceNet Specification.  
Connecting pins 2 and 3 of a jumper configures the PXI-8461 physical  
layer to be powered internally (from the board). In this configuration, the  
V– signal serves as the reference ground for the isolated signals.  
The PCMCIA-CAN is shipped with the bus power version of the  
PCMCIA-CAN cable. An internally-powered version of the  
PCMCIA-CAN cable can be ordered from National Instruments.  
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Appendix B  
Cabling Requirements  
Cable Specifications  
Cables should meet the requirements of the DeviceNet cable specification.  
DeviceNet cabling requirements can be found in the DeviceNet  
Specification.  
Belden cable (3084A) meets all of those requirements and should be  
suitable for most applications.  
Cable Lengths  
The allowable cable length is affected by the characteristics of the cabling  
and the desired bit transmission rates. Detailed cable length requirements  
can be found in the DeviceNet Specification.  
Table B-2 lists the DeviceNet cable length specifications.  
Table B-2. DeviceNet Cable Length Specifications  
Drop Length  
Maximum  
Drop Length  
Cumulative  
Baud Rate  
500 kb/s  
Trunk Length  
100 m (328 ft)  
250 m (820 ft)  
500 m (1640 ft)  
6 m (20 ft)  
6 m (20 ft)  
6 m (20 ft)  
39 m (128 ft)  
78 m (256 ft)  
156 m (512 ft)  
250 kb/s  
125 kb/s  
Maximum Number of Devices  
The maximum number of devices that you can connect to a DeviceNet port  
depends on the electrical characteristics of the devices on the network. If all  
of the devices on the network meet the DeviceNet specifications,  
64 devices may be connected to the network.  
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Appendix B  
Cabling Requirements  
Cable Termination  
The pair of signal wires (CAN_H and CAN_L) constitutes a transmission  
line. If the transmission line is not terminated, each signal change on the  
line causes reflections that may cause communication failures.  
Because communication flows both ways on the DeviceNet bus, DeviceNet  
requires that both ends of the cable be terminated. However, this  
requirement does not mean that every device should have a termination  
resistor. If multiple devices are placed along the cable, only the devices on  
the ends of the cable should have termination resistors. Refer to Figure B-7  
for an example of where termination resistors should be placed in a system  
with more than two devices.  
DeviceNet  
Device  
DeviceNet  
Device  
DeviceNet  
Device  
CAN_H  
CAN_L  
DeviceNet  
Device  
120  
120 Ω  
Figure B-7. Termination Resistor Placement  
The termination resistors on a cable should match the nominal impedance  
of the cable. DeviceNet requires a cable with a nominal impedance of  
120 ; therefore, a 120 resistor should be used at each end of the cable.  
Each termination resistor should each be capable of dissipating at least  
0.25 W of power.  
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Appendix B  
Cabling Requirements  
Cabling Example  
Figure B-8 shows an example of a cable to connect two DeviceNet devices.  
5-Pin  
Combicon  
9-Pin  
D-Sub  
9-Pin  
D-Sub Combicon  
5-Pin  
CAN_H  
CAN_L  
GND  
V+  
Pin 4  
Pin 2  
Pin 3  
Pin 5  
Pin 1  
Pin 7  
Pin 2  
Pin 5  
Pin 9  
Pin 3  
Pin 7  
Pin 2  
Pin 5  
Pin 9  
Pin 3  
Pin 4  
Pin 2  
Pin 3  
Pin 5  
Pin 1  
120  
120 Ω  
V–  
Power  
Connector  
V+  
V–  
Figure B-8. Cabling Example  
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C
Troubleshooting and  
Common Questions  
This appendix describes how to troubleshoot problems with the NI-DNET  
software and answers some common questions.  
Troubleshooting with the Measurement & Automation  
Explorer (MAX)  
MAX contains configuration information for all CAN (DeviceNet)  
hardware installed on your system. To start MAX, double-click on the  
Measurement & Automation icon on your desktop. Your CAN cards are  
listed in the left pane (Configuration) under Devices and Interfaces.  
You can test your CAN cards by choosing Tools»NI-CAN»Test all Local  
NI-CAN Cards from the menu, or you can right-click on an CAN card and  
choose Self Test. If the Self Test fails, refer to the Troubleshooting Self Test  
Failures section of this appendix.  
Missing CAN Card  
If you have a CAN card installed, but no CAN card appears in the  
configuration section of MAX under Devices and Interfaces, you need to  
search for hardware changes by pressing <F5> or choosing the Refresh  
option from the View menu in MAX.  
If the CAN card still doesn’t show up, you may have a resource conflict in  
the Windows Device Manager. Refer to the documentation for your  
Windows operating system for instructions on how to resolve the problem  
using the Device Manager.  
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Appendix C  
Troubleshooting and Common Questions  
Troubleshooting Self Test Failures  
The following topics explain common error messages generated by the Self  
Test in MAX.  
Application In Use  
This error occurs if you are running an application that is using the  
CAN card. The self test aborts to avoid adversely affecting your  
application. Before running the self test, exit all applications that use  
NI-DNET or NI-CAN. If you are using LabVIEW, you may need to exit  
LabVIEW to unload the NI-DNET driver.  
Memory Resource Conflict  
This error occurs if the memory resource assigned to a CAN card conflicts  
with the memory resources being used by other devices in the system.  
Resource conflicts typically occur when your system contains legacy  
boards that use resources not properly reserved with the Device Manager.  
If a resource conflict exists, write down the memory resource that caused  
the conflict and refer to the documentation for your Windows operating  
system for instructions on how to use the Device Manager to reserve  
memory resources for legacy boards. After the conflict has been resolved,  
run the Self Test again.  
Interrupt Resource Conflict  
This error occurs if the interrupt resource assigned to a CAN card conflicts  
with the interrupt resources being used by other devices in the system.  
Resource conflicts typically occur when your system contains legacy  
boards that use resources not properly reserved with the Device Manager.  
If a resource conflict exists, write down the interrupt resource that caused  
the conflict and refer to the documentation for your Windows operating  
system for instructions on how to use the Device Manager to reserve  
interrupt resources for legacy boards. After the conflict has been resolved,  
run the Self Test again.  
NI-CAN Software Problem Encountered  
This error occurs if the Self Test detects that it is unable to communicate  
correctly with the CAN hardware using the installed NI-CAN or NI-DNET  
software. If you get this error, shut down your computer, restart it, and run  
the Self Test again.  
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Appendix C  
Troubleshooting and Common Questions  
If the error continues after restart, uninstall NI-CAN (and NI-DNET) and  
then reinstall.  
NI-CAN Hardware Problem Encountered  
This error occurs if the Self Test detects a defect in the CAN hardware. If  
you get this error, write down the numeric code shown with the error and  
contact National Instruments.  
Common Questions  
How can I determine which version of the NI-DNET software is  
installed on my system?  
Within MAX, open the Software branch and select NI-DNET. The version  
is displayed in the right pane of MAX.  
How many CAN cards can I configure for use with my NI-DNET  
software?  
The NI-DNET software can be configured to communicate with up to  
32 CAN cards on all supported operating systems.  
Which CAN hardware for DeviceNet does the NI-DNET software  
support?  
The NI-DNET software for supports Port 1, Series 1, High-Speed (HS)  
cards. Although you can use 2-port CAN cards, only the top port can be  
used with NI-DNET. For more information, refer to Chapter 2, NI-DNET  
Hardware Overview.  
Does NI-DNET support 2-port CAN cards?  
Refer to the previous question.  
Are interrupts required for the NI-CAN cards?  
Yes, one interrupt per card is required. However, PCI and PXI CAN cards  
can share interrupts with other devices in the system.  
Does the CAN card provide power to the CAN bus?  
No. To provide power to the CAN bus, you need an external power supply.  
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Appendix C  
Troubleshooting and Common Questions  
Can I use multiple PCMCIA cards in one computer?  
Yes, but make sure there are enough free resources available. Unlike PCI  
or PXI CAN cards, PCMCIA CAN cards cannot share resources, such as  
IRQs, with other devices.  
I have problems with my NI PCMCIA CAN card under Windows NT.  
How can I resolve them?  
Windows NT offers minimal support for plug and play and there are several  
things to consider.  
Because Windows NT does not automatically assign resources to PCMCIA  
cards, the PCMCIA CAN cards are configured to use default values for the  
IRQ and the memory range. If those resources are already in use by other  
devices, it might be necessary to manually change those values.  
To do so, right-click the PCMCIA CAN card in MAX and choose  
Properties. Assign resource values that do not conflict with other device  
resources for either the Interrupt Request (IRQ) or the Memory Range.  
Initially, all NI PCMCIA CAN cards will have the same resources  
assigned. If you have more than one PCMCIA CAN card installed, the Self  
Test will fail. You must change the resources of one of the cards manually.  
Windows NT does not allow more than one PCMCIA card of the same type  
installed. Thus, you cannot use two NI PCMCIA cards in the same system.  
Why are some components left after the NI-DNET software is  
uninstalled?  
The uninstall program removes only items that the installation program  
installed. If you add anything to a directory that was created by the  
installation program, the uninstall program does not delete that directory,  
because the directory is not empty after the uninstallation. You must  
remove any remaining components yourself.  
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D
Hardware Specifications  
This appendix describes the physical characteristics of the DeviceNet  
hardware, along with the recommended operating conditions.  
PCI-CAN Series  
Dimensions............................................. 10.67 by 17.46 cm  
(4.2 by 6.9 in.)  
Power requirement ................................. +5 VDC, 775 mA typical  
I/O connector.......................................... 5-pin Combicon-style pluggable  
DeviceNet screw terminal  
(high-speed CAN only)  
Operating environment  
Ambient temperature ...................... 0 to 55 °C  
Relative humidity............................ 10 to 90%, noncondensing  
Storage environment  
Ambient temperature ...................... –20 to 70 °C  
Relative humidity............................ 5 to 90%, noncondensing  
PCMCIA-CAN Series  
Dimensions............................................. 8.56 by 5.40 by 0.5 cm  
(3.4 by 2.1 by 0.4 in.)  
Power requirement ................................. 500 mA typical  
I/O connector.......................................... Cable with 9-pin D-SUB and  
pluggable screw terminal for  
each port  
Operating environment  
Ambient temperature ...................... 0 to 55 °C  
Relative humidity............................ 10 to 90%, noncondensing  
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Appendix D  
Hardware Specifications  
Storage environment  
Ambient temperature.......................–20 to 70 °C  
Relative humidity ............................5 to 90%, noncondensing  
PXI-CAN Series  
Dimensions .............................................16.0 by 10.0 cm  
(6.3 by 3.9 in.)  
Power requirement..................................+5 VDC, 775 mA typical  
I/O connector ..........................................9-pin D-SUB for each port  
(standard)  
or  
5-pin Combicon-style pluggable  
DeviceNet screw terminal  
(high-speed CAN only)  
Operating environment  
Ambient temperature.......................0 to 55 °C  
Relative humidity ............................10 to 90%, noncondensing  
Storage environment  
Ambient temperature.......................–20 to 70 °C  
Relative humidity ............................5 to 95%, noncondensing  
(Tested in accordance with IEC-60068-2-1, IEC-60068-2-2,  
IEC-60068-2-56.)  
Functional Shock ....................................30 g peak, half-sine, 11ms pulse  
(Tested in accordance with IEC-60068-2-27. Test profile developed in  
accordance with MIL-T-28800E.)  
Random Vibration  
Operating.........................................5 to 500 Hz, 0.3 grms  
Nonoperating...................................5 to 500 Hz, 2.4 grms  
(Tested in accordance with IEC-60068-2-64. Nonoperating test profile  
developed in accordance with MIL-T-28800E and MIL-STD-810E  
Method 514.)  
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Appendix D  
Hardware Specifications  
Port Characteristics  
Safety  
Bus power .............................................. 0 to 30 V, 40 mA typical,  
100 mA maximum  
CAN-H, CAN-L..................................... –8 to +18 V, DC or peak, CATI  
The NI-CAN hardware meets the requirements of the following standards  
for safety and electrical equipment for measurement, control, and  
laboratory use:  
EN 61010-1, IEC 61010-1  
UL 3111-1, UL 61010B-1  
CAN/CSA C22.2 No. 1010.1  
Note For UL and other safety certifications, refer to the product label, or visit  
ni.com/hardref.nsf, search by model number or product line, and click the  
appropriate link in the Certification column.  
Pollution Degree .................................... 2  
Maximum altitude.................................. 2,000 m  
Indoor use only.  
Electromagnetic Compatibility  
Electrical emissions................................ EN 55011 Class A at 10 m FCC  
Part 15A above 1 GHz  
Electrical immunity................................ Evaluated to EN 61326:1997  
+A2:2001, Table 1  
CE, C-Tick, and FCC Part 15 (Class A) Compliant  
Note For EMC compliance, operate this device with shielded cabling.  
© National Instruments Corporation  
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Appendix D  
Hardware Specifications  
CE Compliance  
This product meets the essential requirements of applicable European  
Directives, as amended for CE marking, as follows:  
Low-Voltage Directive (safety)..............73/23/EEC  
Electromagnetic Compatibility  
Directive (EMC).....................................89/336/EEC  
Note Refer to the Declaration of Conformity (DoC) for this product for any additional  
regulatory compliance information. To obtain the DoC for this product, visit  
ni.com/hardref.nsf, search by model number or product line, and click the  
appropriate link in the Certification column.  
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E
Technical Support and  
Professional Services  
Visit the following sections of the National Instruments Web site at  
ni.comfor technical support and professional services:  
Support—Online technical support resources at ni.com/support  
include the following:  
Self-Help Resources—For immediate answers and solutions,  
visit the award-winning National Instruments Web site for  
software drivers and updates, a searchable KnowledgeBase,  
product manuals, step-by-step troubleshooting wizards, thousands  
of example programs, tutorials, application notes, instrument  
drivers, and so on.  
Free Technical Support—All registered users receive free Basic  
Service, which includes access to hundreds of Application  
Engineers worldwide in the NI Developer Exchange at  
ni.com/exchange. National Instruments Application Engineers  
make sure every question receives an answer.  
Training and Certification—Visit ni.com/trainingfor  
self-paced training, eLearning virtual classrooms, interactive CDs,  
and Certification program information. You also can register for  
instructor-led, hands-on courses at locations around the world.  
System Integration—If you have time constraints, limited in-house  
technical resources, or other project challenges, NI Alliance Program  
members can help. To learn more, call your local NI office or visit  
ni.com/alliance.  
If you searched ni.comand could not find the answers you need, contact  
your local office or NI corporate headquarters. Phone numbers for our  
worldwide offices are listed at the front of this manual. You also can visit  
the Worldwide Offices section of ni.com/niglobalto access the branch  
office Web sites, which provide up-to-date contact information, support  
phone numbers, email addresses, and current events.  
© National Instruments Corporation  
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Glossary  
Symbol  
Prefix  
milli  
kilo  
Value  
10–3  
103  
m
k
A
A
amperes  
AC  
alternating current  
actuator  
A device that uses electrical, mechanical, or other signals to change  
the value of an external, real-world variable. In the context of device  
networks, actuators are devices that receive their primary data value from  
over the network; examples include valves and motor starters. Also known  
as final control element.  
ANSI  
American National Standards Institute  
Application  
Programming Interface  
(API)  
A collection of functions used by a user application to access hardware.  
Within NI-DNET, you use API functions to make calls into the NI-DNET  
driver.  
ASCII  
American Standard Code for Information Exchange  
Assembly Object  
Objects in DeviceNet devices which route I/O message contents to/from  
individual attributes in the device.  
attribute  
The externally visible qualities of an object; for example, an instance  
square of class Geometric Shapes could have the attributes length of sides  
and color, with the values 4 in. and blue.  
automatic polling  
A polled I/O mode in which NI-DNET automatically determines an  
appropriate scanned polling rate for your DeviceNet system.  
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Glossary  
B
b
Bits  
background polling  
A polled I/O communication scheme in which all polled slaves are grouped  
into two different communication rates: a foreground rate and a slower  
background rate.  
bit strobed I/O  
Master/slave I/O connection in which the master broadcasts a single strobe  
command to all strobed slaves then receives a strobe response from each  
strobed slave.  
C
CAN  
Controller Area Network  
change-of-state I/O  
Master/slave I/O connection which is similar to cyclic I/O but data can be  
sent when a change in the data is detected.  
class  
A classification of things with similar qualities.  
client  
In explicit messaging connections, the client is the device requesting  
execution of the service.  
common services  
connection  
Services defined by the DeviceNet specification such that they are largely  
interoperable.  
An association between two or more devices on a network that describes  
controller  
A device that receives data from sensors and sends data to actuators to hold  
one or more external, real-world variables at a certain level or condition.  
A thermostat is a simple example of a controller.  
COS I/O  
See change-of-state I/O.  
cyclic I/O  
Master/slave I/O connection in which the slave (or master) sends data at a  
fixed interval.  
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Glossary  
D
DC  
direct current  
device  
A physical assembly, linked to a communication line (cable), capable of  
communicating across the network according to a protocol specification.  
device network  
device profiles  
direct entry  
Multi-drop digital communication network for sensors, actuators, and  
controllers.  
DeviceNet specifications which provide interoperability for devices of the  
same type.  
Microsoft Win 32 functions used to directly access the functions of a  
Dynamic Link Library (DLL).  
DLL  
Dynamic Link Library  
driver attributes  
Attributes of the NI-DNET driver software.  
E
EDS  
Electronic Data Sheet. Text file that describes DeviceNet device features  
electronically.  
expected packet rate  
The rate (in milliseconds) at which a DeviceNet connection is expected to  
transfer its data.  
Explicit messaging  
connection  
General-purpose connection used for executing services on a particular  
object in a DeviceNet device.  
F
FCC  
Federal Communications Commission  
ft  
feet  
FTP  
File transfer protocol  
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Glossary  
H
hex  
Hexadecimal  
Hertz  
Hz  
I
I/O connection  
Connection used for exchange of physical input/output (sensor/activator)  
data, as well as other control-oriented data.  
in.  
inches  
individual polling  
A polled I/O communication scheme in which each polled slave  
communicates at its own individual rate.  
instance  
ISO  
A specific instance of a given class. For example, a blue square of 4 inches  
per side would be one instance of the class Squares.  
International Standards Organization  
Kilobytes of memory  
K
KB  
L
LabVIEW  
Laboratory Virtual Instrument Engineering Workbench  
light-emitting diode  
LED  
local  
Within NI-DNET, anything that exists on the same host (personal  
computer) as the NI-DNET driver.  
M
m
meter  
MAC ID  
Media access control layer identifier. In DeviceNet, a device’s MAC ID  
represents its address on the DeviceNet network.  
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Glossary  
master/slave  
DeviceNet communication scheme in which a master device allocates  
connections to one or more slave devices, and those slave devices can only  
communicate with the master and not one another.  
MB  
Megabytes of memory  
member  
method  
multi-drop  
Individual data value within a DeviceNet I/O Assembly.  
See service.  
A physical connection in which multiple devices communicate with one  
another along a single cable.  
N
network interface  
A device’s physical connection onto a network.  
network management  
utility  
Utility used to manage configuration of DeviceNet devices.  
network who  
NI-DNET driver  
notification  
A search of a DeviceNet network to determine information about its  
devices.  
Device driver and/or firmware that implement all the specifics of a  
National Instruments DeviceNet interface.  
Within NI-DNET, an operating system mechanism that the NI-DNET  
driver uses to communicate events to your application. You can think of a  
notification of as an API function, but in the opposite direction.  
O
object  
See instance.  
object-oriented  
A software design methodology in which classes, instances, attributes, and  
methods are used to hide all of the details of a software entity that do not  
contribute to its essential characteristics.  
ODVA  
Open DeviceNet Vendor’s Association  
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Glossary  
P
PC  
personal computer  
peer-to-peer  
DeviceNet communication scheme in which each device communicates as  
a peer and connections are established among devices as needed.  
PLC  
Programmable Logic Controller  
polled I/O  
Master/slave I/O connection in which the master sends a poll command to  
a slave, then receives a poll response from that slave.  
protocol  
A formal set of conventions or rules for the exchange of information among  
devices of a given network.  
R
RAM  
Random-access memory  
remote  
Within NI-DNET, anything that exists in another device of the device  
network (not on the same host as the NI-DNET driver).  
resource  
Hardware settings used by National Instruments DeviceNet hardware,  
including an interrupt request level (IRQ) and an 8 KB physical memory  
range (such as D0000to D1FFFhex).  
S
s
seconds  
scanned polling  
A polled I/O communication scheme in which all poll commands are sent  
out at the same rate, in quick succession.  
sensor  
server  
A device that measures electrical, mechanical, or other signals from an  
external, real-world variable; in the context of device networks, sensors are  
devices that send their primary data value onto the network; examples  
include temperature sensors and presence sensors. Also known as  
transmitter.  
In explicit messaging connections, the server is the device to which the  
service is directed.  
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Glossary  
service  
An action performed on an instance to affect its behavior; the externally  
visible code of an object. Within NI-DNET, you use NI-DNET functions  
to execute services for objects. Also known as method and operation.  
strobed I/O  
See bit strobed I/O.  
V
V
volts  
VI  
VxD  
Virtual Instrument  
Virtual device driver  
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Index  
C
error message  
change protocol, 1-3  
memory resource conflict, C-2  
NI-CAN hardware problem encountered,  
C-2  
uninstall, C-4  
examples (NI resources), E-1  
NI-CAN card and power to CAN bus, C-3  
problems with NI PCMCIA CAN card  
under Windows NT, C-4  
troubleshooting with MAX, C-1  
using multiple PCMCIA cards, C-4  
configure DNET port, 1-3  
conventions used in the manual, x  
conventions, related documentation, x  
installation and configuration  
NI-DNET cards listed in MAX (figure), 1-2  
verifying through MAX, 1-1  
D
change protocol, 1-3  
instrument drivers (NI resources), E-1  
interrupt resource conflict, troubleshooting, C-2  
diagnostic tools (NI resources), E-1  
documentation  
conventions, x  
how to use manual set, ix  
NI resources, E-1  
related conventions, x  
drivers (NI resources), E-1  
K
KnowledgeBase, E-1  
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Index  
L
R
LabVIEW Real-Time (RT)  
software configuration, 1-3  
related documentation, x  
S
safety specifications, D-3  
SimpleWho, 1-4  
M
MAX  
1-2  
tools launched from, 1-3  
software  
Measurement & Automation Explorer  
(MAX). See MAX  
configuration, 1-3  
memory resource conflict, troubleshooting,  
C-2  
software (NI resources), E-1  
specifications  
missing CAN card, troubleshooting, C-1  
CE compliance, D-4  
electromagnetic compatibility, D-3  
PCI-CAN series board, D-1  
safety, D-3  
N
National Instruments support and services,  
E-1  
NI-CAN software problem encountered,  
troubleshooting, C-2  
NI-DNET  
(figure), 1-2  
NI-Spy, 1-4  
T
technical support, E-1  
training and certification (NI resources), E-1  
missing CAN card, C-1  
NI-CAN software problem encountered,  
C-2, C-3  
P
D-1  
self-test failures, C-2  
with MAX, C-1  
port characteristics, D-3  
programming examples (NI resources), E-1  
PXI-8461  
troubleshooting (NI resources), E-1  
port characteristics, D-3  
W
Web resources, E-1  
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ni.com  

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