National Instruments Digital Camera NI 1450 Series User Manual |
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The NI 1450 Series Compact Vision System 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 during the warranty period. This warranty includes parts and labor.
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notice of such defects during the warranty period. National Instruments does not warrant that the operation of the software shall be
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Compliance
FCC/Canada Radio Frequency Interference Compliance
Determining FCC Class
The Federal Communications Commission (FCC) has rules to protect wireless communications from interference. The FCC
places digital electronics into two classes. These classes are known as Class A (for use in industrial-commercial locations only)
or Class B (for use in residential or commercial locations). All National Instruments (NI) products are FCC Class A products.
Depending on where it is operated, this Class A product could be subject to restrictions in the FCC rules. (In Canada, the
Department of Communications (DOC), of Industry Canada, regulates wireless interference in much the same way.) Digital
electronics emit weak signals during normal operation that can affect radio, television, or other wireless products.
All Class A products display a simple warning statement of one paragraph in length regarding interference and undesired
operation. The FCC rules have restrictions regarding the locations where FCC Class A products can be operated.
FCC/DOC Warnings
This equipment generates and uses radio frequency energy and, if not installed and used in strict accordance with the instructions
in this manual and the CE marking Declaration of Conformity*, may cause interference to radio and television reception.
Classification requirements are the same for the Federal Communications Commission (FCC) and the Canadian Department of
Communications (DOC).
Changes or modifications not expressly approved by NI could void the user’s authority to operate the equipment under the FCC
Rules.
Class A
Federal Communications Commission
This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of the FCC
Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated
in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and
used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this
equipment in a residential area is likely to cause harmful interference in which case the user is required to correct the interference
at their own expense.
Canadian Department of Communications
This Class A digital apparatus meets all requirements of the Canadian Interference-Causing Equipment Regulations.
Cet appareil numérique de la classe A respecte toutes les exigences du Règlement sur le matériel brouilleur du Canada.
Compliance to EU Directives
Readers in the European Union (EU) must refer to the manufacturer’s Declaration of Conformity (DoC) for information*
pertaining to the CE marking compliance scheme. The manufacturer includes a DoC for most hardware products except for those
bought from OEMs. In addition, DoCs are usually not provided if compliance is not required, for example electrically benign
apparatus or cables.
To obtain the DoC for this product, click Declarations of Conformity Information at ni.com/hardref.nsf/. This Web site
lists the DoCs by product family. Select the appropriate product family, followed by your product, and a link to the DoC appears
in Adobe Acrobat format. Click the Acrobat icon to download or read the DoC.
*
The CE marking Declaration of Conformity contains important supplementary information and instructions for the user or
installer.
Conventions
The following conventions are used 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
pull down the File menu, select the Page Setup item, and select Options
from the last dialog box.
This icon denotes a tip, which alerts you to advisory information.
This icon denotes a note, which alerts you to important information.
This icon denotes a caution, which advises you of precautions to take to
avoid injury, data loss, or a system crash.
bold
Bold text denotes items that you must select or click in the software, such
as menu items and dialog box options. Bold text also denotes hardware
labels and 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, and code excerpts.
monospace bold
Bold text in this font denotes the messages and responses that the computer
automatically prints to the screen. This font also emphasizes lines of code
that are different from the other examples.
Chapter 1
NI 1450 Overview
Hardware Overview.......................................................................................................1-1
Available Camera Bandwidth........................................................................................1-3
Software Overview ........................................................................................................1-4
National Instruments Application Software ....................................................1-5
Chapter 2
Setup and Configuration
Required Items...............................................................................................................2-1
Software...........................................................................................................2-2
Accessories ....................................................................................................................2-2
Documentation...............................................................................................................2-3
Hardware Documents ......................................................................................2-3
Vision Builder AI Documents.........................................................................2-3
Documents....................................................................................................2-3
Wiring Power to the NI 1450............................................................2-9
Connecting the NI 1450 to the Development Computer...................2-11
Vision Builder AI: Setting up the Development Computer...........................................2-12
Installing Vision Builder AI and NI-IMAQ for IEEE 1394 Cameras.............2-13
Configuring the IP Address and Downloading Software onto the NI 1450....2-13
Acquiring an Image in Vision Builder AI.......................................................2-14
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Contents
Development Computer.............................................................................................. 2-15
Installing LabVIEW Real-Time, Vision Development Module,
Configuring the IP Address using LabVIEW Real-Time ............................... 2-16
Chapter 3
LEDs, DIP Switches, and Connectors
SAFE MODE Switch...................................................................................... 3-4
IEEE 1394....................................................................................................... 3-8
VGA................................................................................................................ 3-8
COM1.............................................................................................................. 3-10
TRIG 0 ............................................................................................................ 3-11
Chapter 4
Digital I/O Functionality
TTL Inputs and Outputs.................................................................................. 4-2
Isolated Inputs and Outputs............................................................................. 4-2
Trigger Inputs.................................................................................................. 4-3
Timed Pulse Output ........................................................................................ 4-4
Initiating a Timed Pulse.................................................................... 4-4
Pulse Modes...................................................................................... 4-5
Pulse Delay....................................................................................... 4-5
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Pulse Width.......................................................................................4-5
Trigger Polarity.................................................................................4-5
Product Selection Port.....................................................................................4-7
General-Purpose I/O........................................................................................4-8
Considerations When Connecting the Digital I/O...........................................4-11
Wiring an Isolated Input to a Sourcing Output Device.....................4-11
Protecting Inductive Loads ...............................................................4-13
Typical System Setup......................................................................................4-14
Chapter 5
Deployment
Connecting Multiple NI 1450s ......................................................................................5-1
Appendix A
Troubleshooting
Appendix B
Specifications
Appendix C
Technical Support and Professional Services
Glossary
Index
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1
NI 1450 Overview
This chapter provides an overview of the features and components on the
National Instruments 1450 Series Compact Vision System.
About the NI 1450 Series Compact Vision System
The NI 1450 Series Compact Vision System is an easy-to-use, distributed,
real-time imaging system that acquires, processes, and displays images
from IEEE 1394 cameras conforming to the IIDC 1394-based Digital
Camera Specification, Version 1.30. The NI 1450 also provides multiple
digital input/output (I/O) options for communicating with external devices
to configure and start an inspection and to indicate results.
An Ethernet connection between the NI 1450 and a development computer
allows you to display measurement results and status information and to
configure the NI 1450 settings. Once configured, the NI 1450 can run
applications without a connection to the development computer.
Each NI 1450 ships with documentation and the NI-IMAQ for IEEE 1394
Cameras driver software, which is licensed for one development system
and one deployment system.
Hardware Overview
The NI 1450 front panel consists of a VGA connector, an RS-232 serial
port, a 10/100 Ethernet connector, and three IEEE 1394a ports.
The NI 1450 also includes LEDs for communicating system status, DIP
switches for mode control for specifying startup options, TTL inputs and
outputs for triggering, and isolated inputs and outputs for connecting to
external devices, such as PLCs, sensors, LED indicators, and start/stop
buttons. The isolated inputs and outputs on the NI 1450 provide an easy
means for preventing ground loops that could degrade signal integrity.
Caution The isolation on the NI 1450 is not safety isolation.
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Figure 1-1 shows the NI 1450 front panel.
1
2
NI 1454
Compact Vision System
3
4
11
10
5
9
8
6
7
1
2
3
4
Power LED
Status LED
Isolated Digital Input
TTL Digital Outputs
5
6
7
8
IEEE 1394a Ports
TTL I/O and Isolated I/O 10 RS-232 Serial
Reset Button
DIP Switches
9
VGA
11 RJ-45 Ethernet Port
Figure 1-1. NI 1450 Series Compact Vision System Front Panel
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Chapter 1
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Available Camera Bandwidth
The IEEE 1394 bus provides a fixed amount of bandwidth that is shared
direct connection to up to three DCAM-compliant IEEE 1394 cameras,
depending on the amount of bandwidth each camera requires. Higher frame
rates and larger image sizes require a higher data transfer rate and use more
bandwidth.
Table 1-1 shows the maximum number of cameras the NI 1450 supports for
three common video formats. Use this table as a guide when determining
the combination of cameras to use in your application. The maximum
number of cameras listed in the table does not include processing time.
By triggering your cameras slower than the frame rates listed in the table,
you can operate more cameras simultaneously. If the camera combination
exceeds the amount of available bandwidth, the software returns an
Insufficient Resources error.
Table 1-1. Available Camera Bandwidth
Maximum Number
of Cameras for
Video Format
Frames per Second Simultaneous Operation
640 x 480,
8-bit/pixel mono
30
60
3
1
1
3
1
100
15
640 x 480 YUV
(4:2:2) 16-bit/pixel
color
30
1024 x 768
16-bit/pixel mono
7.5
15
2
1
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Software Overview
Programming the NI 1450 Series Compact Vision System requires the
NI-IMAQ for IEEE 1394 Cameras driver software, version 1.5 or later,
to control the hardware and one of the following application software
packages to process images.
•
NI Vision Builder for Automated Inspection (AI), version 2.0 or
later—To configure solutions to common inspection tasks
•
LabVIEW Real-Time (RT), version 7.0 or later, with the Vision
Development Module, version 7.0 or later—For customizable
control over acquisition hardware and algorithms
The following sections provide an overview of the driver software and the
application software. For detailed information about individual software
packages, refer to the documentation specific to the package.
NI-IMAQ for IEEE 1394 Cameras Driver Software
The NI-IMAQ for IEEE 1394 Cameras driver software ships with the
NI 1450 Series Compact Vision System. NI-IMAQ for IEEE 1394
Cameras is the interface path between the application software and the
NI 1450.
NI-IMAQ for IEEE 1394 Cameras includes an extensive library of VIs
you can call from LabVIEW. These VIs include routines for video
configuration, image acquisition (continuous and single-shot), trigger
control, and register-level camera configuration.
The NI-IMAQ for IEEE 1394 Cameras driver software performs all
functions necessary for acquiring and saving images but does not perform
image analysis. For image analysis functionality, refer to the National
Instruments Application Software section.
For maximum flexibility and performance, NI-IMAQ for IEEE 1394
Cameras features both high-level and low-level functions. A function that
acquires images in multi-buffer, single-shot, or continuous mode is an
example of a high-level function. A function that requires advanced
understanding of the NI 1450 and image acquisition, such as configuring
an image sequence, is an example of a low-level function.
The NI-IMAQ for IEEE 1394 Cameras software handles many of the
complex issues between the NI 1450 and the camera, such as 1394 bus
communication and camera control.
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National Instruments Application Software
Vision Builder for Automated Inspection
National Instruments Vision Builder for Automated Inspection (AI) is
configurable machine vision software that you can use to prototype,
benchmark, and deploy applications. NI Vision Builder AI does not require
programming, but is scalable to LabVIEW RT.
Vision Builder AI allows you to easily configure and benchmark a
sequence of visual inspection steps, as well as deploy the visual inspection
system for automated inspection. With Vision Builder AI, you can perform
powerful visual inspection tasks and make decisions based on the results of
individual tasks. Additionally, you can communicate with external devices
using an Ethernet connection, serial lines, and digital I/Os. With Vision
Builder AI, you can migrate your configured inspection to LabVIEW,
extending the capabilities of your applications if necessary.
LabVIEW RT with the Vision Development Module
The LabVIEW Real-Time Module and the RT Series hardware, such as the
NI 1450, extend the capabilities of LabVIEW to address the need for
deterministic real-time performance.
The Real-Time Module combines LabVIEW graphical programming with
the power of RT Series hardware, enabling you to build deterministic
real-time systems. You develop VIs in LabVIEW and embed the VIs on
RT targets. The RT target runs VIs without a user interface and offers a
stable platform for real-time VIs.
For more information about LabVIEW RT, refer to the LabVIEW
Real-Time Module User Manual.
The Vision Development Module is an image acquisition, processing, and
analysis library of more than 270 functions for grayscale, color, and binary
image display, image processing, pattern matching, particle analysis,
gauging, and measurement.
For unique image processing, you can use the Vision Development Module
functions individually or in combination. The Vision Development Module
allows you to acquire, display, manipulate, and store images as well as
perform image analysis, processing, and interpretation. Using the Vision
Development Module, imaging novices and experts can program the most
basic or complicated image applications without knowledge of particular
algorithm implementations.
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Vision Assistant is an interactive prototyping tool for machine vision and
scientific imaging developers and is included with the Vision Development
Module. With Vision Assistant, you can prototype vision applications
quickly and test how various vision image processing functions work.
For information about how to use the Vision Development Module with
LabVIEW RT, refer to the IMAQ Vision for LabVIEW User Manual.
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2
Setup and Configuration
This chapter provides instructions for connecting the NI 1450 Series
Compact Vision System hardware. This chapter also includes instructions
for installing software, configuring an IP address, and acquiring an initial
image using the application software.
Required Items
The following items are necessary for connecting the NI 1450.
Hardware
❑ NI 1450 Series Compact Vision System
❑ Ethernet-equipped development computer running
Windows XP/2000/Me/98
❑ DCAM-compliant IEEE 1394 camera
❑ IEEE 1394 jackscrew-to-latch cable (part number 778796-01) or any
standard IEEE 1394 cable—for plug-and-play connection from the
NI 1450 to up to three 1394 cameras. You can use a 4-pin to 6-pin
converter cable with cameras that have their own external power
supply and do not require power from the 1394 bus.
Note To maintain signal integrity, the IEEE 1394 cable length must be no longer
than 4.5 m.
❑ NI desktop power supply (part number 778794-01) or any
24 VDC 10%, 50 W power supply
❑ Power supply cord—for connecting the NI desktop power supply to an
outlet. Refer to ni.comfor ordering information for the part number
specific to your region.
Note If you are using the NI desktop power supply, you will need a power cord.
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❑ 4-position power connector—required if you are not using the
NI desktop power supply
❑ 10 m 10/100Base-T Ethernet cable (part number
189174-10)—standard CAT 5 10/100Base-T Ethernet cable for
connecting the NI 1450 to a network port. To connect the NI 1450
directly to a local development computer, use an Ethernet crossover
cable.
Note To maintain signal integrity, the Ethernet cable length must be no longer than 100 m.
Software
❑ NI-IMAQ for IEEE 1394 Cameras driver software, which includes the
NI 1450 support software
❑ One of the following application software packages:
•
National Instruments Vision Builder for Automated Inspection
(AI), version 2.0 or later
•
National Instruments LabVIEW Real-Time, version 7.0 or later,
with the Vision Development Module, version 7.0 or later
Accessories
National Instruments offers the following accessories for use with the
NI 1450.
Hardware
•
•
•
•
•
VGA-resolution camera (part number 778785-01)
12 mm fixed focal length lens (part number 778789-01)
LED ring light (part number 778787-01)
DIN rail/panel mount kit (part number 189154-01)
Digital I/O cable and horizontal DIN rail terminal block (part number
778790-01)
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•
•
•
Digital I/O cable and vertical DIN rail terminal block (part number
778791-01)
75 Ω SMB 111 coaxial cable (part number 763422-01)— SMB to
BNC cable for connecting to triggers and light sources
10 m Ethernet crossover cable (part number 187375-10)—for
connecting the NI 1450 directly to the development computer
Documentation
The documentation resources listed in this section ship with the NI 1450
and the application software. For more resources, including code examples
and tutorials, visit the National Instruments Developer Zone at
ni.com/zone.
Hardware Documents
•
NI 1450 Series Compact Vision System User Manual
NI 1450 Series Compact Vision System Digital I/O Help
•
Vision Builder AI Documents
•
•
•
NI Vision Builder for Automated Inspection Tutorial
NI Vision Builder for Automated Inspection: Configuration Help
NI Vision Builder for Automated Inspection: Inspection Help
LabVIEW Real-Time Module with the Vision Development Module
Documents
NI-IMAQ for IEEE 1394 Cameras Driver Software
Documents
•
•
•
•
Getting Started with NI-IMAQ for IEEE 1394 Cameras
NI-IMAQ for IEEE 1394 Cameras User Manual (PDF)
NI-IMAQ for IEEE 1394 Cameras VI Reference Help
MAX Help for NI-IMAQ for IEEE 1394 Cameras
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LabVIEW Real-Time Module and Vision
Development Module Documents
•
•
•
•
•
•
NI Vision Assistant Help
NI Vision Assistant Tutorial
IMAQ Vision Concepts Manual
IMAQ Vision for LabVIEW User Manual
IMAQ Vision for LabVIEW Help
LabVIEW Real-Time Module documentation
Safety Information
Caution The following paragraphs contain important safety information you must follow
when installing and operating the device.
Do not operate the device in a manner not specified in the documentation.
Misuse of the device may result in a hazard and may compromise the safety
protection built into the device. If the device is damaged, turn it off and do
not use it until service-trained personnel can check its safety. If necessary,
return the device to National Instruments for repair.
Keep away from live circuits. Do not remove equipment covers or shields
unless you are trained to do so. If signal wires are connected to the device,
hazardous voltages can exist even when the equipment is turned off. To
avoid a shock hazard, do not perform procedures involving cover or shield
removal unless you are qualified to do so. Disconnect all field power prior
to removing covers or shields.
If the device is rated for use with hazardous voltages (>30 Vrms, 42.4 Vpk,
or 60 Vdc), it may require a safety earth-ground connection wire. Refer to
the device specifications for maximum voltage ratings.
Because of the danger of introducing additional hazards, do not install
unauthorized parts or modify the device. Use the device only with the
chassis, modules, accessories, and cables specified in the installation
instructions. All covers and filler panels must be installed while operating
the device.
Do not operate the device in an explosive atmosphere or where flammable
gases or fumes may be present. Operate the device only at or below the
pollution degree stated in the specifications. Pollution consists of any
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foreign matter—solid, liquid, or gas—that may reduce dielectric strength
or surface resistivity. Pollution degrees are listed below.
•
Pollution Degree 1—No pollution or only dry, nonconductive
pollution occurs. The pollution has no effect.
•
Pollution Degree 2—Normally only nonconductive pollution occurs.
Occasionally, nonconductive pollution becomes conductive because of
condensation.
•
Pollution Degree 3—Conductive pollution or dry, nonconductive
pollution occurs. Nonconductive pollution becomes conductive
because of condensation.
Clean the device and accessories by brushing off light dust with a soft,
nonmetallic brush. Remove other contaminants with a stiff, nonmetallic
brush. The unit must be completely dry and free from contaminants before
returning it to service.
You must insulate signal connections for the maximum voltage for which
the device is rated. Do not exceed the maximum ratings for the device.
Remove power from signal lines before connection to or disconnection
from the device.
Caution National Instruments measurement products may be classified as either
Installation Category I or II. Operate products at or below the Installation Category level
specified in the hardware specifications.
Installation Category1: Measurement circuits are subjected to working
voltages2 and transient stresses (overvoltage) from the circuit to which they
are connected during measurement or test. Installation Category establishes
standardized impulse withstand voltage levels that commonly occur in
electrical distribution systems. The following is a description of Installation
(Measurement3) Categories:
•
Installation Category I is for measurements performed on circuits not
directly connected to the electrical distribution system referred to as
MAINS4 voltage. This category is for measurements of voltages from
specially protected secondary circuits. Such voltage measurements
include signal levels, special equipment, limited-energy parts of
1
2
3
4
Installation Categories as defined in electrical safety standard IEC 61010-1.
Working voltage is the highest rms value of an AC or DC voltage that can occur across any particular insulation.
Installation Category is also referred to as Measurement Category.
MAINS is defined as the (hazardous live) electrical supply system to which equipment is deisgned to be connected for the
purpose of powering the equipment. Suitably rated measuring circuits may be connected to the MAINS for measuring
purposes.
© National Instruments Corporation
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equipment, circuits powered by regulated low-voltage sources, and
electronics.
•
Installation Category II is for measurements performed on circuits
directly connected to the electrical distribution system. This category
refers to local-level electrical distribution, such as that provided by a
standard wall outlet (e.g., 115 V for U.S. or 230 V for Europe).
Examples of Installation Category II are measurements performed on
household appliances, portable tools, and similar products.
•
•
Installation Category III is for measurements performed in the building
installation at the distribution level. This category refers to
measurements on hard-wired equipment such as equipment in fixed
installations, distribution boards, and circuit breakers. Other examples
are wiring, including cables, bus-bars, junction boxes, switches,
socket-outlets in the fixed installation, and stationary motors with
permanent connections to fixed installations.
Installation Category IV is for measurements performed at the primary
electrical supply installation (<1,000 V). Examples include electricity
and on ripple control units.
Connection Overview
Figure 2-1 illustrates the sequence for connecting and getting started with
the NI 1450.
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Setup and Configuration
Set Up the Hardware
Set Up the Development
Computer Using LabVIEW
Real-Time with the Vision
Development Module
Set Up the Development
Computer Using
Vision Builder AI
or
or
Acquire an Image Using
LabVIEW Real-Time with the
Vision Development Module
Acquire an Image Using
Vision Builder AI
Figure 2-1. Connection Sequence
•
•
Set up the hardware—This section explains how to connect a camera,
monitor, and power supply to the NI 1450.
Set up the development computer—This section explains how to use
either Vision Builder AI or LabVIEW Real-Time with the Vision
Development Module to perform the following tasks:
–
–
–
Connect the NI 1450 to the development computer
Install application and driver software
Obtain an IP address
•
Acquire an image—This section explains how to use either Vision
Builder AI or LabVIEW Real-Time with the Vision Development
Module to acquire an image.
Before Getting Started: Connecting the NI 1450 to a Network
Use a standard Category 5 or Category 6 Ethernet cable to connect the
NI 1450 to an Ethernet network.
If the development computer is already configured on a network, you must
configure the NI 1450 on the same network. If the development computer
is not connected to a network, you can connect the two directly using a
Category 5 or Category 6 crossover cable.
Caution To prevent data loss and to maintain the integrity of your Ethernet installation,
do not use a cable longer than 100 m. If you are using a 100 Mbps Ethernet, National
Instruments recommends using a Category 5 or Category 6 shielded twisted-pair
Ethernet cable.
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Setup and Configuration
Subnet Considerations
To configure the NI 1450, it must reside on the same subnet as the
development computer. Once the NI 1450 is configured, other subnets can
access and use it.
To use the NI 1450 on a subnet other than the one the development
computer is on, first connect and configure it on the same subnet as the
development computer. Next, physically move it to the other subnet and
reassign an IP address. Contact your network administrator for assistance
in setting up the development computer and NI 1450 on the same subnet.
Hardware Setup
This section describes how to connect the basic hardware components of
the NI 1450. When these basic components are connected for the first time,
the NI 1450 runs a program that acquires images. This program verifies that
all hardware components are properly connected and functioning.
The following items are necessary for hardware setup.
❑ NI 1450 Series Compact Vision System
❑ 24 VDC 10%, 50 W power supply
❑ DCAM-compatible IEEE 1394 camera
❑ IEEE 1394 cable
❑ Ethernet cable
❑ Monitor
Before connecting a camera and monitor to the NI 1450, make sure that all
NI 1450 DIP switches are in the OFF position.
To connect an IEEE 1394 camera and a monitor to the NI 1450, refer to
Figure 2-2 while completing the following steps:
1. Connect the VGA cable from the monitor to the VGA port on the
NI 1450.
NI 1450. Plug the other end of the cable into the IEEE 1394 receptacle
on the camera.
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If your camera requires an external power supply, connect it to the
camera and verify that the camera is powered on.
3. Plug in and power on the monitor.
1
2
1
VGA Cable
2
IEEE 1394 Cable
Wiring Power to the NI 1450
This section describes how to connect the NI desktop power supply.
For instructions on how to connect a separate main supply, refer to the
Connecting to a Separate Main Supply section.
Caution Do not connect the NI 1450 main power to a source other than 24 VDC 10%.
Do not connect the NI 1450 isolated power to a source less than 5 VDC or greater than
30 VDC. Doing so could damage the NI 1450.
To connect power to the NI 1450, refer to Figure 2-3 while completing the
following steps:
1. Plug the 4-position connector from the power supply into the power
receptacle on the NI 1450.
3. Plug the power cord into an outlet.
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Setup and Configuration
The NI 1450 ships with a factory-installed startup program that, when the
NI 1450 is connected to a camera and powered on, acquires images and
displays them on the monitor. If these images from the camera display on
the monitor, continue to the Connecting the NI 1450 to the Development
Computer section. If the images from the camera are not displayed on the
monitor, refer to Appendix A, Troubleshooting.
To Outlet
1
2
3
1
4-Position Power Connector
2
NI Desktop Power Supply
3
Power Supply Cord (to Outlet)
Figure 2-3. Wiring Power to the NI 1450
Connecting to a Separate Main Supply
If you are using a power supply other than the NI desktop power supply,
use this section to connect power to the NI 1450.
Caution Do not connect the NI 1450 main power to a source other than 24 VDC 10%.
Do not connect the NI 1450 isolated power to a source less than 5 VDC or greater than
30 VDC. Doing so could damage the NI 1450.
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The NI 1450 ships with a 4-position power connector that plugs directly
into the power input connector on the NI 1450. To wire power to the
4-position connector, complete the following steps:
1. Wire the voltage output of the 24 VDC 10% power supply to the main
voltage input, labeled V, on the 4-position connector.
2. Wire the common (ground) output of the power supply to the common
input, labeled C, on the 4-position connector.
If you are using a separate power supply for the NI 1450 isolated outputs,
connect the voltage output on the power supply to the isolated power (Viso)
on the 4-position connector. Connect the common (ground) on the power
Note If you do not require a separate power supply for the NI 1450 isolated outputs,
you can daisy-chain the V to the Viso and the C to the Ciso on the connector.
For information about grounding the NI 1450 chassis to earth ground, refer
to the Earth Ground Connection section of Chapter 3, LEDs, DIP Switches,
and Connectors.
Connecting the NI 1450 to the Development
Computer
The development computer communicates with the NI 1450 over an
Ethernet connection. Use a standard Ethernet cable to connect from the
network port to the NI 1450. To connect the NI 1450 directly to the
development computer, use an Ethernet crossover cable.
To connect the NI 1450 to the development computer, refer to Figure 2-4
while completing the following steps:
1. Verify that the development computer is connected to the network and
is powered on.
2. Using a standard CAT 5 Ethernet cable, connect from the network port
to the Ethernet port on the NI 1450.
3. Using a standard CAT 5 Ethernet cable, connect from the network port
to the Ethernet port on the development computer.
Note If you are not connecting through a network, use an Ethernet crossover cable to
connect the NI 1450 directly to the development computer.
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1
2
1
2
3
Standard Ethernet Cable Connecting from the NI 1450 to an Ethernet Hub
Standard Ethernet Cable Connecting from an Ethernet Hub to the Development Computer
Ethernet Hub or Other Network Port
Figure 2-4. Ethernet Connection
Vision Builder AI: Setting up the Development Computer
This section describes the sequence for installing Vision Builder AI and the
obtaining an IP address, installing software on the NI 1450, and
configuring the NI 1450 to acquire an image using Vision Builder AI.
This section applies only to Vision Builder AI users. If you are using
LabVIEW RT with the Vision Development Module, refer to the LabVIEW
Real-Time with the Vision Development Module: Setting up the
Development Computer section.
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The following items are necessary for setting up the development
computer.
❑ Vision Builder AI software, version 2.0 or later
❑ NI-IMAQ for IEEE 1394 Cameras driver software, version 1.5 or later
Installing Vision Builder AI and NI-IMAQ for IEEE 1394 Cameras
This section describes how to install the Vision Builder AI software and the
NI-IMAQ for IEEE 1394 Cameras driver software onto the development
computer.
Note You must install Vision Builder AI before installing the NI-IMAQ for IEEE 1394
Cameras driver software.
Complete the following steps to install Vision Builder AI and the NI-IMAQ
for IEEE 1394 Cameras driver software onto the development computer.
1. Insert the Vision Builder AI CD into the CD-ROM drive.
2. When the installation splash screen appears, click Install NI Vision
Builder AI 2.0 and follow the setup instructions.
3. Insert the NI-IMAQ for IEEE 1394 Cameras CD into the CD-ROM
drive.
Note When installing NI-IMAQ for IEEE 1394 Cameras, make sure to install the support
files for LabVIEW Real-Time.
4. When the installation splash screen appears, click Install NI-IMAQ
for IEEE 1394 Cameras and follow the setup instructions.
5. Reboot the development computer.
Configuring the IP Address and Downloading Software onto the NI 1450
To set up an IP address and download software onto the NI 1450, complete
the following steps:
1. Launch Vision Builder AI by navigating to Start»Programs»
National Instruments»Vision Builder AI.
2. Expand the Execution Target pull-down listbox and click Select
3. In the Select Remote Target window, click 192.168.10.12 to highlight
the row. This IP address is assigned to all unconfigured NI 1450s.
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Tip To uniquely identify unconfigured NI 1450s, connect and configure one NI 1450
at a time.
4. Click Configure to launch the Vision Builder AI Remote Target
Configuration Wizard.
5. In the Identification window, enter a name for the NI 1450 in the
Name field and a description of the NI 1450 in the Description field.
Note Device names are limited to 15 characters with no spaces or special characters.
The first and last characters must be alphanumeric.
6. Click Next.
7. If the network is configured to issue IP addresses using DHCP, select
Obtain IP address from DHCP server. Otherwise, set the IP address
manually by selecting Edit IP Settings, Suggest Values, and OK.
8. Click Next. This window shows the status of the software installed on
the NI 1450.
9. Select the Update Target Software checkbox.
10. Click OK to begin configuring the IP address and downloading
software onto the NI 1450. This initialization process takes several
minutes.
Acquiring an Image in Vision Builder AI
To acquire an image in Vision Builder AI, complete the following steps:
1. Launch Vision Builder AI.
2. In the Vision Builder AI Welcome screen, expand the Execution
Target pull-down listbox and click Select Network Target.
3. Select the NI 1450 you configured and click OK.
4. In the Vision Builder AI Welcome screen, click Configure
Inspection.
5. From the Acquire Images palette, click Acquire Image (IEEE 1394).
6. Click the Snap button to acquire a single image, or click the Grab
button to acquire continuous images.
7. Once you have configured your acquisition, click OK to add the step.
You can now add inspection steps as documented in the NI Vision
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LabVIEW Real-Time with the Vision Development
Module: Setting up the Development Computer
This section describes the sequence for installing the application and driver
software on the development computer, obtaining an IP address, installing
software on the NI 1450, and configuring the NI 1450 to acquire an image
using LabVIEW Real-Time.
This section applies only to LabVIEW Real-Time users. If you are using the
Vision Builder AI software, refer to the Vision Builder AI: Setting up the
Development Computer section.
The following items are necessary for setting up the development
computer.
❑ LabVIEW and LabVIEW Real-Time software
❑ Vision Development Module software
❑ NI-IMAQ for IEEE 1394 Cameras driver software
Installing LabVIEW Real-Time, Vision Development Module,
and NI-IMAQ for IEEE 1394 Cameras
Note You must install LabVIEW, LabVIEW Real-Time, and the Vision Development
Module software before installing the NI-IMAQ for IEEE 1394 Cameras driver software.
Complete the following steps to install LabVIEW, LabVIEW Real-Time,
the Vision Development Module, and the NI-IMAQ for IEEE 1394
Cameras software onto the development computer.
1. Insert the LabVIEW CD into the CD-ROM drive.
2. When the installation splash screen appears, click Install LabVIEW
and follow the setup instructions.
3. Insert the LabVIEW Real-Time CD into the CD-ROM drive.
4. When the installation splash screen appears, click Install LabVIEW
Real-Time and follow the setup instructions.
5. Insert the Vision Development Module CD into the CD-ROM drive.
Module and follow the setup instructions.
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7. Insert the NI-IMAQ for IEEE 1394 Cameras CD into the CD-ROM
drive.
Note If you select the custom software installation, make sure to install the support for the
NI 1450 Series Compact Vision System.
8. When the splash screen appears, click Install NI-IMAQ for
IEEE 1394 Cameras and follow the setup instructions.
9. When prompted, click Yes to reboot the development computer.
Configuring the IP Address using LabVIEW Real-Time
To set up an IP address for the NI 1450, complete the following steps:
1. Open the Measurement & Automation Explorer (MAX) configuration
software by double-clicking the MAX icon on the desktop, or navigate
to it by selecting Start»Programs»National Instruments»
Measurement & Automation.
2. Expand the Remote Systems branch of the configuration tree, and
click 192.168.10.12 to display the Network Settings window.
This IP address is assigned to all unconfigured NI 1450s.
Tip To uniquely identify unconfigured NI 1450s, connect and configure one NI 1450
at a time.
3. In the Network Settings window, enter a name for the device in the
Name field and a description of the device in the Comment field.
Note Device names are limited to 15 characters with no spaces or special characters.
The first and last characters must be alphanumeric.
4. If the network is configured to issue IP addresses using DHCP, select
Obtain IP address from DHCP server. Otherwise, set the IP address
manually by selecting Edit the IP settings, Suggest Values, and OK.
5. Click Apply.
6. When prompted, click Yes to reboot the NI 1450. This initialization
process takes several minutes.
While the NI 1450 is rebooting, an icon
appears next to the device
name to indicate that the NI 1450 is disconnected. The MAX status bar
also indicates the connection status of the NI 1450.
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Downloading Software onto the NI 1450
1. In the MAX configuration window, click the Software tab. This
window displays the status of the software on the NI 1450.
2. Click the Install Software button.
3. Select the software to download. For initial installation, make sure all
checkboxes are selected.
4. Click OK.
5. When prompted, click Yes to reboot the NI 1450. This process takes
several seconds.
Acquiring an Image Using LabVIEW Real-Time
To acquire an image using LabVIEW Real-Time, complete the following
steps:
1. Launch LabVIEW by navigating to Start»Programs»National
Instruments LabVIEW 7.0.
2. Expand the Execution Target pull-down listbox and click Select
Target with Options.
3. Enter the new IP address in the Machine Name/IP field and click OK.
4. Click the Open button.
5. Navigate to ProgramFiles\NationalInstruments\
LabVIEW7.0\examples\IMAQ.
6. Double-click IMAQ1394examples.llband select Grab.vi.
7. Click the Run button to begin acquiring images.
Now that you are acquiring images in LabVIEW, you can use the Vision
Development Module and the installed NI 1450 drivers to process images
and to control inputs and outputs.
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3
LEDs, DIP Switches, and
This chapter provides information about the location and functionality of
the LED indicators, DIP switches, and connectors on the NI 1450. The
connector.
LED Indicators
Figure 3-1 shows the location of the POWER OK and STATUS LEDs on
the NI 1450.
STATUS
NI 1454
Compact Vision System
POWER OK
Figure 3-1. POWER OK and STATUS LEDs
Refer to Appendix A, Troubleshooting, for information about
troubleshooting LEDs.
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POWER OK LED
Under normal operating conditions, the POWER OK LED remains green
while the NI 1450 is powered on. A green POWER OK LED indicates that
NI 1450 main power is receiving power and that the NI 1450 is not in a fault
state. A red POWER OK LED indicates that the NI 1450 has shut down
because of a fault state. A fault state occurs when the user shutdown input
is asserted, the processor overheats, or the watchdog timer expires.
Note The POWER OK LED does not indicate the status of the isolated power, Viso.
STATUS LED
The orange STATUS LED remains off under normal operating conditions
and flashes a specific number of times to indicate error conditions or certain
DIP switch settings. The STATUS LED remains lit if the NI 1450 detects
an internal error.
Refer to the Hardware Errors section of Appendix A, Troubleshooting,
for information about LED error indications.
ACT/LINK LED
100 Mbps LED
The orange ACT/LINK LED blinks when the NI 1450 receives data from
or transmits data to the network through the Ethernet connection. Unrelated
network activity causes this LED to blink occasionally even when the
NI 1450 is inactive.
Figure 3-2 shows the location of the ACT/LINK LED on the NI 1450.
The green 100 Mbps LED is lit when the network provides 100 Mbps
support and the NI 1450 is communicating at 100 Mbps. If the 100 Mbps
LED is not lit, the NI 1450 is not operating at 100 Mbps.
Figure 3-2 shows the location of the 100 Mbps LED on the NI 1450.
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NI 1454
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Figure 3-2. ACT/LINK and 100 Mbps LEDs
DIP Switches
This section describes the SAFE MODE, IP RESET, NO APP, and
USER 1 DIP switches on the NI 1450.
To enable a DIP switch, move it to the ON (left) position and then reset the
NI 1450 by pressing the RESET button for at least two seconds.
Note You must reset the NI 1450 in order for the setting change to occur.
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Figure 3-3 shows the location of the DIP switches on the NI 1450.
NI 1454
Compact Vision System
ON
Figure 3-3. DIP Switches
SAFE MODE Switch
To boot the NI 1450 in Safe mode, move the SAFE MODE switch to the
ON position and reset the NI 1450. Use safe mode to reconfigure TCP/IP
settings and to download or update software from the development
computer.
Downloading incorrect software to the NI 1450 may cause it to hang on
reboot or become inaccessible over the network. Powering on or resetting
the NI 1450 in SAFE MODE starts the NI 1450 but does not start the
embedded LabVIEW RT engine. To resume normal operations, reboot the
NI 1450 with the SAFE MODE switch in the OFF position.
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IP RESET Switch
To clear the NI 1450 IP settings, move the IP RESET switch to the ON
position and reset the NI 1450. Use IP RESET to reset the TCP/IP settings
when moving the system from one subnet to another or when the current
TCP/IP settings are invalid.
Resetting the NI 1450 with the IP RESET switch in the ON position resets
the IP address to 0.0.0.0. You can then set up a new network configuration
for the NI 1450 from a development machine on the same subnet, or you
can use an Ethernet crossover cable to connect the NI 1450 directly to the
development computer.
NO APP Switch
To prevent the NI 1450 from automatically running VIs at startup, move
the NO APP switch to the ON position and reset the NI 1450. If the
NI 1450 becomes inaccessible because of a startup program, enable the
NO APP switch and reset the NI 1450.
Enable this switch to prevent the NI 1450 default startup program or Vision
Builder AI from running at startup.
USER 1 Switch (LabVIEW RT Users)
The USER 1 switch is user-configurable and has no default functionality.
You can use the RT Read Switch VI to read the USER 1 switch state and
perform a custom action based on the current switch state position.
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LEDs, DIP Switches, and Connectors
Connectors
This section describes the connectors on the NI 1450 and includes pinouts
and signal descriptions for each connector.
Table 3-1 summarizes the functions of the connectors on the NI 1450.
Table 3-1. NI 1450 Connectors Overview
Peripheral
External Connectors
Function
Power
4-position power
connector
Main power and power for isolated outputs
IEEE 1394a
VGA
6-pin IEEE 1394
Power and data connection to IEEE 1394
cameras
15-pin female DSUB
(standard VGA)
Video output
Serial
9-pin male DSUB
(standard RS-232 serial
port)
COM1
10/100 Ethernet
RJ-45 (standard
Ethernet port)
Ethernet network connection
TRIG 0
SMB receptacle
SMB receptacle
External isolated trigger input
External TTL output
TRIG 1 and TRIG 2
Digital Input/Output
44-pin female
External TTL I/O; External isolated I/O
high-density DSUB
Power Connector
The power connector on the NI 1450 accommodates two power supplies.
The terminals labeled V and C provide the voltage and common for the
main power of the NI 1450. The terminals labeled Viso and Ciso provide
the voltage and common to power the isolated output circuitry.
Caution The isolation provided by the NI 1450 is intended to prevent ground loops that
could introduce noise into the system. This isolation does not provide safety isolation.
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Figure 3-4 shows the power connector on the NI 1450, and Table 3-2
describes each terminal on the connector.
POWER
POWER
Ciso
Ciso
Viso
Viso
(5-30 VDC)
(5-30 VDC)
C
V
(24 VDC 10%)
C
V
(24 VDC 10%)
Figure 3-4. Power Connector
Table 3-2. Power Connector Terminals
Terminal
Description
Main power (24 VDC 10%)
Common
V
C
Viso
Ciso
Isolated power (5 to 30 VDC)
Isolated common
Earth Ground Connection
Some system setups may require using the grounding lug on the NI 1450 to
connect the chassis to earth ground. Connecting the grounding lug, shown
in Figure 3-5, to earth ground connects the common of the main power to
earth ground through the NI 1450 chassis.
Note An earth ground connection does not connect Ciso to earth ground.
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1
POWER
Ciso
Viso
(5-30VDC)
2
C
V
(24VDC 10%)
1
Grounding Lug
2
Power Connector
Figure 3-5. Grounding Lug on the NI 1450
IEEE 1394
The IEEE 1394 connectors on the NI 1450 provide a reliable,
high-frequency connection between the NI 1450 and to up to
three DCAM-compatible IEEE 1394 cameras. For information about
the amount of bandwidth available for connecting cameras, refer to the
Available Camera Bandwidth section of Chapter 1, NI 1450 Overview.
To access the IEEE 1394 connectors on the NI 1450, use any standard 6-pin
IEEE 1394 cable.
Note You can use a 4-pin to 6-pin converter cable with cameras that have their own
VGA
The VGA connector on the NI 1450 provides connection between the
NI 1450 and a VGA monitor. Use any standard 15-pin VGA cable to access
the VGA connector. Figure 3-6 shows the VGA connector location and
pinout. Table 3-3 lists and describes the VGA connector signals.
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NI 1454
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1
6
11
5
10 15
Figure 3-6. VGA Connector
Table 3-3. VGA Connector Signals
Pin
1
Signal Name
Signal Description
R
G
Red
2
Green
Blue
3
B
4
NC
C
No Connect
5
Common of the NI 1450 main power
Common of the NI 1450 main power
Common of the NI 1450 main power
Common of the NI 1450 main power
+5V
6
C
7
C
8
C
9
+5V
C
10
11
12
13
14
15
Common of the NI 1450 main power
No Connect
NC
SD
HSync
VSync
SC
Serial Data
Horizontal Sync
Vertical Sync
Serial Clock
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COM1
serial devices, such as PLCs, scanners, and lighting devices.
Note The Serial Port VIs access COM1 as Port 0.
Figure 3-7 shows the locations of the COM1 DSUB 9-pin connector.
Refer to Table 3-4 for COM1 signal names and descriptions
NI 1454
Compact Vision System
5 9
1 6
Figure 3-7. COM1 DSUB 9-Pin Connector
Table 3-4. COM1 Connector Signals
Pin
1
Signal Name
DCD
RXD
TXD
DTR
C
Signal Description
Data Carrier Detect
2
Receive Data
3
Transmit Data
4
Data Terminal Ready
Common of the NI 1450 main power
Data Set Ready
5
6
DSR
RTS
7
Ready to Send
Clear to Send
9
RI
Ring Indicator
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Ethernet
TRIG 0
The Ethernet port on the NI 1450 provides connection between the NI 1450
and the development computer, either directly or through a network port.
The NI 1450 automatically detects the speed of the connection
and configures itself accordingly.
If you are connecting the NI 1450 to the development computer through
a network port, use a standard Ethernet cable. To connect the NI 1450
directly to the development computer, use an Ethernet crossover cable.
The TRIG 0 isolated input on the NI 1450 provides connection to
external devices, such as proximity sensors and start/stop buttons. For easy
coaxial cable (part number 763422-01).
Note Additional isolated inputs are available on the 44-pin DSUB connector.
Caution These isolated inputs are compatible with 5 V logic if the external circuit meets
the voltage and current requirements listed in Appendix B, Specifications.
TRIG 1 and TRIG 2
You can use the two TTL outputs available on the SMB connectors for
triggering cameras and external interfaces, such as lighting control units.
For easy connection to the TTL outputs, use the National Instruments SMB
111 coaxial cable (part number 763422-01).
Note Additional TTL outputs are available on the 44-pin DSUB connector.
Caution Do not connect voltage or current sources to TTL outputs. Doing so could
damage the NI 1450.
General-Purpose Digital I/O
The 44-pin DSUB connector, shown in Figure 3-8, provides access to the
general-purpose digital inputs and outputs. The general-purpose digital I/O
available on this connector includes two TTL inputs, eight TTL outputs,
twelve isolated inputs, and four isolated outputs. For easy connection to the
digital I/O connector, use the National Instruments digital I/O cable and
terminal block.
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For detailed information about digital I/O functionality and recommended
use cases, refer to Chapter 4, Digital I/O Functionality.
Note Isolated inputs are compatible with 5 V logic if the external circuit meets the voltage
and current requirements listed in Appendix B, Specifications.
NI 1454
Compact Vision System
44 30 15
31 16 1
Figure 3-8. 44-Pin DSUB Connector
Table lists pin numbers, signal names, and signal descriptions for the
44-pin connector on the NI 1450 and the 37-pin terminal block.
Caution Do not draw more than 500 mA combined from the Viso pins on the 44-pin
DSUB connector. Do not draw more than 100 mA from each isolated output.
Table 3-5. 44-Pin DSUB and 37-Pin Terminal Block Connector Signals
44-Pin
DSUB on
NI 1450
37-Pin
Terminal
Block
Pin Number Pin Number
Signal Name
TTL Input 0
C
Primary Function
Alternate Function
1
2
1
3
Pulse generator trigger input General-purpose input
Common of the NI 1450
main power
—
3
4
TTL Output 0
Watchdog output
General-purpose output
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Table 3-5. 44-Pin DSUB and 37-Pin Terminal Block Connector Signals (Continued)
44-Pin
DSUB on
NI 1450
37-Pin
Terminal
Block
Pin Number Pin Number
Signal Name
TTL Output 1
C
Primary Function
Alternate Function
General-purpose output
—
4
5
5
6
Pulse generator output
Common of the NI 1450
main power
6
7
8
7
8
6
TTL Output 2
TTL Output 3
C
Pulse generator output
Pulse generator output
General-purpose output
General-purpose output
—
Common of the NI 1450
main power
9
NC
17
18
19
35
34
9
NC
No connect
—
—
—
—
—
—
—
10
11
12
13
14
15
16
17
Viso
Isolated power
Ciso
Isolated common
General-purpose output
General-purpose output
Isolated common
Input port, Data(0)
ISO Output 0
ISO Output 1
Ciso
ISO Input 0
TTL Input 1
C
2
Pulse generator trigger input General-purpose input
3
Common of the NI 1450
main power
—
18
19
20
20
21
22
TTL Output 4
TTL Output 5
C
Pulse generator output
General-purpose output
General-purpose output
—
—
Common of the NI 1450
main power
21
22
23
23
24
22
TTL Output 6
TTL Output 7
C
General-purpose output
General-purpose output
—
—
—
Common of the NI 1450
main power
24
25
NC
33
NC
No connect
—
—
Viso
Isolated power
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LEDs, DIP Switches, and Connectors
Table 3-5. 44-Pin DSUB and 37-Pin Terminal Block Connector Signals (Continued)
44-Pin
DSUB on
NI 1450
37-Pin
Terminal
Block
Pin Number Pin Number
Signal Name
Ciso
Primary Function
Isolated common
Alternate Function
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
34
36
37
12
10
11
13
16
14
15
28
25
26
28
27
29
32
30
31
—
—
—
—
—
—
—
—
—
—
—
ISO Output 2
ISO Output 3
Ciso
General-purpose output
General-purpose output
Isolated common
ISO Input 1
ISO Input 2
ISO Input 3
Ciso
Input port, Data(1)
Input port, Data(2)
Input port, Data(3)
Isolated common
ISO Input 4
ISO Input 5
Ciso
Input Port, Data(4)
Input port latch, Data(5)
Isolated common
ISO Input 6
ISO Input 7
Ciso
Quadrature encoder Phase A General-purpose input
Quadrature encoder Phase B General-purpose input
Isolated common
—
ISO Input 8
ISO Input 9
Ciso
Pulse generator trigger input General-purpose input
General-purpose input
Isolated common
General-purpose input
—
ISO Input 10
ISO Input 11
General-purpose input
User shutdown
General-purpose input
General-purpose input
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4
Digital I/O Functionality
This chapter describes the primary functions of the digital inputs and
outputs on the NI 1450 Series Compact Vision System. This chapter also
includes guidelines for connecting the digital I/O and for setting up a
typical NI 1450 system.
Overview
The digital I/O functions are accessible through 2 TTL inputs, 10 TTL
outputs, 13 isolated inputs, and 4 isolated outputs.
Input signals can be used as triggers, product selection ports, to read
quadrature encoders, or they can be user-defined. Uses for output signals
include controlling camera reset and exposure, controlling strobe lighting,
outputting inspection results, communicating with PLCs, or they can be
user defined.
For information about how to use LabVIEW RT to implement specific
digital I/O functions, refer to the application software documentation and
examples in the following locations:
• ProgramFiles\NationalInstruments\NI1450Series\Docs
• ProgramFiles\NationalInstruments\LabVIEW7.0\
examples\NI1450
The NI 1450 Series Compact Vision System Digital I/O Help is available
for each example. This help file contains digital I/O reference information
and instructions for using the LabVIEW FPGA VIs.
Tip To quickly launch the digital I/O help from an example, press <F1>.
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Digital I/O Functionality
TTL Inputs and Outputs
TTL is a fast-switching 5 V digital signaling standard commonly used
TTL inputs and outputs do not require a separate power supply.
Caution Do not connect voltage or current sources to TTL outputs. Doing so could
damage the NI 1450.
Table 4-1 summarizes the TTL inputs and outputs available on the NI 1450.
Table 4-1. TTL Inputs and Outputs
44-Pin DSUB
on NI 1450
Pin Number
37-Pin
Terminal Block
Pin Number
Primary
Function
Input or
Output
Number
Available
Signal Names
TTL Input 0
Trigger
Input
2
6
1
16
1
2
TTL Input 1
Timed Pulse
Output
TRIG 1, Pulse 5
TRIG 2, Pulse 6
TTL Output 1, Pulse 1
TTL Output 2, Pulse 2
TTL Output 3, Pulse 3
TTL Output 4, Pulse 4
—
—
4
6
7
—
—
5
7
8
18
20
Watchdog
Output
Output
1
3
TTL Output 0
3
4
General-Purpose
TTL Output 5
TTL Output 6
TTL Output 7
19
21
22
21
23
24
Isolated Inputs and Outputs
reference from the main NI 1450 supply, providing an easy means to
prevent ground loops that can introduce noise into a system. You can apply
signals up to 30 V to the isolated inputs. The voltage swing of the isolated
outputs is determined by the Viso you supply on the connector.
Table 4-2 summarizes the isolated inputs and outputs available on the
NI 1450.
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Table 4-2. Isolated Inputs and Outputs
44-Pin DSUB
on NI 1450
Pin Number
37-Pin
TerminalBlock
Pin Number
Input or
Output
Number
Available Signal Names
Primary Function
Trigger
Input
3
TRIG 0
ISO Input 5†
ISO Input 8
—
35
40
—
15
27
Quadrature Encoder
Input
Input
Input
1
1
1
ISO Input 6
ISO Input 7
37
38
25
26
External Shutdown
Control
ISO Input 11
44
31
Product Selection Port†
ISO Input 0
ISO Input 1
ISO Input 2
ISO Input 3
ISO Input 4
15
30
31
32
34
9
10
11
13
14
General-Purpose
General-Purpose
Input
2
4
ISO Input 9
ISO Input 10
41
43
29
30
Output
ISO Output 0
ISO Output 1
ISO Output 2
ISO Output 3
12
13
27
28
19
35
36
37
† ISO Input 5 can also function as a latch for the product selection port.
Trigger Inputs
Trigger inputs are available from both TTL inputs and isolated inputs. You
can use these trigger inputs to synchronize the NI 1450 with an external
event, such as the assertion of a signal generated by a proximity sensor or
a PLC to indicate that an inspection item is passing in front of the camera.
The NI 1450 uses this input to initiate a timed pulse that can be used for
camera control, lighting control, encoder pulse counting, and result output
timing.
For more information about creating a timed pulse output, refer to the
Timed Pulse Output section.
Alternatively, the ISO Input 5 signal can function as a latch input for
the product selection port, and all five trigger inputs can function as
general-purpose inputs.
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Digital I/O Functionality
Timed Pulse Output
The NI 1450 is capable of timed pulse output on six different digital
outputs, which provides precise control over time-critical signals, such as
camera exposure. This section describes the various uses for the timed
pulse output and the parameters you can set to control these outputs.
Uses for timed pulse output include controlling camera reset and exposure,
controlling strobe lighting, operating plungers on an assembly line, and
communicating with PLCs. You can configure the start of the pulse output
generation to occur from software or from a rising or falling edge of a
trigger input.
In addition to controlling the timing of pulse output, you can also configure
the polarity of the output signal, resulting in a high-true or low-true signal.
Based on the polarity setting, the output signal asserts after the appropriate
delay time and de-asserts after the configured pulse width. You can set the
delay time in microseconds or in quadrature encoder counts from the start
signal—either a hardware trigger or a software command. Width is always
configured in microseconds.
Initiating a Timed Pulse
Each timed pulse generator has a trigger input that specifies whether to wait
on a particular trigger input to generate the pulse or to immediately
generate the pulse when software sets the mode to Start.
When the pulse generator is configured for a particular trigger input, after
generating a pulse, it waits for another trigger before generating another
pulse. When the pulse generator is configured to immediately generate the
pulse on a software start, after generating a pulse, it immediately generates
another pulse.
If the trigger input is set to immediate, the pulse generation occurs as soon
as the pulse mode is set to start. If the trigger input is set to one of the
hardware trigger inputs, the timed pulse output waits for an assertion edge
on the appropriate trigger input. The assertion edge is configurable based
on the trigger polarity parameter. It then generates one pulse and rearms to
wait for the next trigger. In either case, the pulse output generation stops
and resets if the pulse mode parameter is set to stop.
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Figure 4-1 shows an output pulse when a trigger is selected.
Trigger
Input
Output
Pulse
Figure 4-1. Output Pulse When Trigger Is Selected
Pulse Modes
Each pulse generator has a Start and a Stop mode. Configure the pulse
generator when in Stop mode and then set it to Start mode.
Pulse Delay
Pulse delay is the amount of time between a trigger and the first (assertion)
edge of an output pulse. The pulse delay is configurable in units of
microseconds or quadrature encoder counts. If configured for
microseconds, available values are between 10 µs and 4,294,967,295 µs,
which is 4,294 seconds, or approximately 71 minutes. If the delay is
configured for quadrature encoder counts, the range of choices is 0 counts
to 4,294,967,295 counts.
Pulse Width
Pulse width is the amount of time between the first (assertion) edge of a
pulse and the second (deassertion) edge. Pulse width is configurable only
in microseconds from 10 µs to 4,294,967,295 µs.
Trigger Polarity
Each pulse generator can be individually configured for rising or falling
edge triggering. Even if multiple pulse generators are using the same
trigger, each can have different polarities.
Figure 4-2 shows the output of a pulse generator configured to look for a
rising edge trigger and output a high pulse with a microsecond width and
delay.
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Digital I/O Functionality
Delay
Width
Trigger
Pulse
Figure 4-2. High Pulse with Rising Edge Trigger
Figure 4-3 shows how to create a high and low pulse train with a
microsecond delay and width.
High Pulse Train
Delay
Width
Delay
Width
Low Pulse Train
Software
Start
Figure 4-3. High and Low Pulse Trains
Quadrature Encoder
The quadrature encoder uses ISO Input 6 for its Phase A input and
ISO Input 7 for its Phase B input. Encoder speed is limited by the speed of
the isolated inputs. Each isolated input can change at a maximum rate of
100 kHz, making the maximum encoder rate 400,000 counts/s.
The quadrature encoder can also be used as a timebase for the pulse
generation delay.
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Figure 4-4 shows a rising edge trigger and a low pulse with a quadrature
encoder delay and a microsecond width.
Trigger
Low Pulse
Delay
Width
Phase A
Phase B
Figure 4-4. Rising Edge Trigger, Low Pulse with a Quadrature Encoder Delay
Product Selection Port
The product selection port consists of a group of five isolated digital inputs
that the software running on the NI 1450 reads simultaneously. You can
program the NI 1450 to switch between up to 32 (25) inspection sequences
for different parts on an assembly line.
Based on the input to the product selection port, you can configure the
application software to run the appropriate inspection sequence. For
example, an upstream NI 1450 programmed for part classification might
drive the product selection port of a downstream NI 1450. Alternatively,
a PLC with information about which part is being inspected can drive the
product selection port of the NI 1450.
Using ISO Input 5 as a Latch
You can configure the product selection port to use ISO Input 5 as a latch.
A rising edge on ISO Input 5 can latch the data into a data register on the
NI 1450. Before each inspection, the software checks the status of the
product select inputs and reads the most recent value latched into the
register.
Note In Vision Builder AI, ISO Input 5 is always designated as a latch.
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Digital I/O Functionality
Table 4-3 lists the product selection ports.
Table 4-3. Product Selection Port
Function
Data(5), rising edge latch
Data(4)
External Connection
ISO Input 5
ISO Input 4
ISO Input 3
ISO Input 2
ISO Input 1
ISO Input 0
Data(3)
Data(2)
Data(1)
Data(0)
General-Purpose I/O
General-Purpose Inputs
General-purpose inputs are available as both TTL and isolated inputs.
At any time, the software running on the NI 1450 can read these inputs.
The primary difference between general-purpose inputs and trigger inputs
is that you cannot use general-purpose inputs to initiate a timed pulse
generator. In an application, use the general-purpose inputs to get the status
of the inputs at a given point and not to synchronize the NI 1450 system
with an external event.
An example of how to use general-purpose inputs is reading the status of
a general-purpose input as the first step in your inspection sequence and
recording that value as part of your inspection.
General-Purpose Outputs
General-purpose outputs are also available as both TTL and isolated
outputs. At any time, the software running on the NI 1450 can drive these
outputs high or low.
The primary difference between general-purpose outputs and timed pulse
outputs is that the timing of general-purpose outputs is controlled by
software rather than hardware. As a result, timing of general-purpose
outputs changes as the inspection algorithm changes, which makes
general-purpose outputs less appropriate than timed outputs for camera
control, strobe light control, and other applications that require precise
timing.
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An example of using general-purpose outputs is driving a relay that turns
on an Inspection in Progress light for an operator to see while the inspection
sequence is running.
Fault Conditions
The NI 1450 recognizes the following fault conditions:
•
•
•
External shutdown, when Shutdown mode is enabled
Watchdog expiration, when configured for system shutdown
Overheat
The behavior of the NI 1450 in the event of a fault condition is dependent
on configuration settings of the SAFE MODE DIP switch and the
software-enabled Shutdown mode.
To resume operation, address the fault condition and reset the NI 1450.
The following sections describe each fault condition, and Table 4-4
summarizes how user configuration affects the behavior of the NI 1450
in the event of a fault condition.
Shutdown
Shutdown mode is a software-enabled feature that when activated allows
an external device to halt the NI 1450 processing operations. Additionally,
enabling Shutdown mode allows you to specify user-defined shutdown
states for all fault conditions.
When Shutdown mode is enabled and the shutdown input signal,
ISO Input 11, turns off, the NI 1450 registers an external shutdown
condition. When this fault occurs, the POWER OK LED turns red and all
system operation halts. To resume operation, you must reset the NI 1450.
For all fault conditions, outputs operate according to user-defined
or 3-state, and each isolated output is on/off configurable.
Because the NI 1450 cannot run VIs in Safe mode, Shutdown mode is
unavailable when the SAFE MODE DIP switch is turned on.
Refer to Table 4-4 for a summary of how user configuration affects the
shutdown condition.
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Digital I/O Functionality
Disabling Shutdown Mode
To disable Shutdown mode once it is enabled, remove Shutdown mode
from the software script and reset the NI 1450. To reset the system, press
the RESET button on the NI 1450 front panel for at least two seconds.
Note For prototyping when equipment is unavailable, you can wire from Viso to
ISO Input 11 to simulate external equipment that indicates to the NI 1450 to operate
normally.
Watchdog
The watchdog timer is a software configurable feature that can monitor
software on the NI 1450 and take action if the software is unresponsive.
The millisecond counter on the watchdog timer is configurable up to
65,534 ms, in 1 ms increments, before it expires.
Configure the watchdog to take one of the following actions when it
expires:
•
Indicator Only—This option sends the expiration signal back to the
development machine through software. True indicates an expired
watchdog timer, and False indicates an unexpired watchdog timer. The
expiration signal that indicates an expired watchdog continues to assert
until the watchdog is disarmed. Disarming the watchdog resets the I/O.
Caution Use the Indicator Only option only to test the watchdog. If software becomes
unresponsive, it cannot be relied upon to send notification to the host.
•
TTL Output 0—This option outputs a signal on TTL Output 0. A High
on TTL Output 0 indicates that the watchdog has expired, and a Low
indicates that it has not expired. If the watchdog timer has expired, the
expiration signal will continue to assert until the watchdog is disarmed.
Note LabVIEW RT supports all watchdog timer options. Vision Builder AI supports only
•
System Shutdown—This option halts the NI 1450 operation and turns
the POWER OK LED red. If Shutdown mode is enabled, the outputs
go to the user-defined shutdown states.
Table 4-4 summarizes how user configuration affects the shutdown
condition.
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Digital I/O Functionality
Overheat
Operating the NI 1450 outside of its temperature specifications may cause
the NI 1450 to overheat. Refer to Appendix B, Specifications, for
temperature specifications.
In the event of an overheat, all NI 1450 operation halts and the
POWER OK LED turns red. If Shutdown mode is enabled, the outputs
go to the user-defined shutdown states.
Table 4-4. Configuration Settings and Effects
Configuration Settings
Configuration Effects
Outputs Change to
Fault
Condition
Safe Mode
DIP
Shutdown
Enabled
Processing Halts
User-Defined States
External
Shutdown
On
Off
Off
On
Off
Off
On
Off
Off
N/A
On
N/A
Yes
No
No
Yes
No
No
Yes
No
No
Yes
No
Off
N/A
On
Watchdog
Overheat
N/A
Yes
Yes
Yes
Yes
Yes
Off
N/A
On
Off
Considerations When Connecting the Digital I/O
isolated. Figure 4-6 shows the trigger input interface circuit.
Wiring an Isolated Input to a Sourcing Output Device
You can wire an isolated input to a sourcing output device, as shown in the
example in Figure 4-5. Refer to Appendix B, Specifications for switching
thresholds and current requirements.
Caution Do not apply a voltage greater than 30 VDC to the isolated inputs. Doing so could
damage NI 1450.
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Digital I/O Functionality
Sourcing
Output
Device
Viso
Vcc
Input
Current
Limiter
Ciso
NI 1450
Figure 4-5. Example of Connecting an Isolated Input to a Sourcing Output Device
Wiring an Isolated Output to an External Load
The digital output circuit sources current to external loads, as shown in
the example in Figure 4-6. The maximum output current of this circuit
is 100 mA.
Viso
Vcc
Digital Output
Load
Ciso
NI 1450
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Protecting Inductive Loads
When an inductive load, such as a relay or solenoid, is connected to an
output, a large counter-electromotive force may occur at switching time
due to energy stored in the inductive load. This flyback voltage can damage
the outputs and the power supply.
To limit flyback voltages at the inductive load, install a flyback diode across
the load. Mount the flyback diode as close to the load as possible. Use this
protection method if you connect any of the isolated outputs on the NI 1450
to an inductive load.
Figure 4-7 shows an example of using an external flyback diode to protect
inductive loads.
Viso
Vcc
Digital
Output
Load
Ciso
External
Flyback
Diode for
NI 1450
Inductive Loads
Figure 4-7. Example of Using an External Flyback Diode for Inductive Loads
Transmission Line Effects
cause instability. To minimize transmission line effects, use twisted-pair
wires with a characteristic impedance of 118Ω to connect external signals
to the 44-pin I/O DSUB connector. Use a 75Ω coaxial cable, such as
RG-179, to connect to the SMB connectors.
Figure 4-8 shows connections to the 44-pin DSUB connector and the
TRIG 0 SMB connector that minimize transmission line effects.
© National Instruments Corporation
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Digital I/O Functionality
TRIG 1
SMB
RG-179
Coaxial Cable
75 Ω
TRIG 1
Receiving
Equipment
44-Pin
DSUB
118 Ω
TTL OUT(0)
3
2
Receiving
Equipment
+5 V
62 kΩ
RS
TTL IN(0)
16
17
Transmitting
Equipment
NI 1450
Figure 4-8. Example Connections
When connecting to TTL inputs on the NI 1450 device, match the output
impedance of the transmitting device to the characteristic impedance of the
cable. For example, if the cable characteristic impedance is 118 Ω, make
Rs equal to 118 Ω, as shown in Figure 4-8.
Typical System Setup
Digital I/O configuration varies depending on the number of cameras your
system setup requires. You can access the digital I/O through the 44-pin
DSUB connector or through the 3 SMB connectors.
The digital I/O capabilities of the SMB connectors on the NI 1450 are ideal
for typical single-camera applications. The SMB connectors are labeled
TRIG 0, TRIG 1, and TRIG 2.
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Table 4-5 summarizes a typical single-camera configuration.
Table 4-5. Typical Single-Camera System Setup
Signal Name
Signal Type
Isolated input
Purpose
TRIG 0
Trigger input from
proximity sensor or
external device
TRIG 1
TRIG 2
Timed pulse TTL output
Timed pulse TTL output
Exposure start and
control signal to camera
Strobe light control
Figure 4-9 shows a typical single-camera setup.
2
1
NI 1454
Compact Vision System
3
4
1
2
Lighting Control Unit
Lighting Ring
3
4
Inspection Items
Proximity Sensor
Figure 4-9. Typical Single-Camera Setup
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
5
Deployment
This chapter provides guidelines for connecting the NI 1450 Series
Compact Vision System to a network.
Connecting Multiple NI 1450s
An Ethernet connection between the development computer and the
NI 1450 allows you to assign an IP address, configure the NI 1450,
download inspection tasks, and remotely monitor an ongoing inspection.
As with all Ethernet devices, you can connect multiple NI 1450s to the
same network, as shown in Figure 5-1.
Figure 5-1. Multiple NI 1450s Connected to the Same Network
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Deployment
To connect multiple NI 1450s to the same network, each NI 1450 must have
a unique IP address. By default, the configuration utility running on the
development computer displays each NI 1450 that exists on the subnet.
To add entries for NI 1450s that exist on other subnets, you must know the
IP address assigned to each NI 1450. This feature allows remote
configuration, programming, and monitoring of any NI 1450 not protected
by a firewall or user password.
Use the NI 1450 serial number and media access control (MAC) address to
uniquely identify each unit. The serial number and MAC address are
printed on the top side of each NI 1450 unit, as shown in Figure 5-2.
Figure 5-2. Serial Number and MAC Address Label on the NI 1450
The configuration environment on the host machine displays these values
in order to distinguish one NI 1450 from another. In addition to
distinguishing units based on serial number and MAC address, you can also
When configured to run an inspection, the NI 1450 can run autonomously
without connection to the host machine. All image acquisition, inspection,
decision making, and I/O occurs on the NI 1450 itself. For local monitoring
of the inspection, you can connect a monitor directly to the Video Out
connector on the NI 1450, as shown in Figure 5-3.
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A
Troubleshooting
This appendix provides instructions for troubleshooting the NI 1450.
Software Configuration Problems
NI 1450 Does Not Appear in MAX or in Vision Builder AI
Possible causes and solutions:
•
Verify that there is power to the NI 1450 and that both the NI 1450 and
the development computer are properly connected to the network.
The POWER OK LED should be lit. When you click Browse,
the ACT/LINK LED on the NI 1450 should flash to indicate that
communications are taking place.
•
Certain network devices, such as switches and routers, may filter out
the directed UDP broadcast packets the development computer uses to
communicate with unconfigured NI 1450s, even if these devices are on
the same subnet. You can test this by connecting the development
computer and the NI 1450 directly to a network port or by using a
crossover cable between the NI 1450 and the development computer.
If the NI 1450 appears in the software using this configuration, but not
when connected to the larger network, the network is not properly
communicating with the NI 1450. Consult your network administrator.
•
•
The NI 1450 may have been configured on another network and then
moved to the current network. Reconfigure the NI 1450 on the current
network.
The grade of cable you are using may be insufficient for the speed of
your network, or you may be using the wrong type of Ethernet cable.
Use a straight-through cable when connecting to network hardware.
Use a crossover cable to connect directly to the development computer.
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Appendix A
Troubleshooting
•
•
Another device on the network is using the IP address assigned to the
NI 1450. Either remove or reconfigure the other device, or reconfigure
the NI 1450 IP address.
The DIP switch settings on the NI 1450 may be invalid, such as all
switches set to the ON position. Change the DIP switch settings and
reset the NI 1450 by pressing the RESET button on the NI 1450 for at
least two seconds.
Error When Configuring IP Settings for the NI 1450
The NI 1450 cannot be configured if the subnet mask or IP address is
incompatible with the network settings. Verify that the values entered for
Status of NI 1450 in MAX and Vision Builder AI is NoSoftware
Installed
Install application and driver software on the NI 1450. Refer to Chapter 2,
Setup and Configuration, for installation instructions.
No Camera Found
Verify that the total power requirements of the cameras do not exceed the
power the NI 1450 provides on the 1394 bus. Verify that the cameras
comply with the IIDC Digital 1394-based Camera Specification,
Version 1.30.
Hardware Errors
POWER OK LED is Red
The NI 1450 is in one of the following fault conditions:
•
Shutdown enabled in software, but ISO Input 11 is not turned on
–
ISO Input 11 is used to indicate to the NI 1450 that all external
devices are ready for operation. When ISO Input 11 turns off, the
NI1450 shuts down. Either turn on ISO Input 11 with an external
source and reset the NI 1450, or disable Shutdown in the software.
Note For prototyping when external equipment is unavailable, Viso can be wired to ISO
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Appendix A
Troubleshooting
•
•
Watchdog expired while configured for the system shutdown option
–
for the processing time. Check the software to determine if it
could monopolize the processor.
Processor overheat
–
Make sure you are operating the NI 1450 in compliance with the
temperature specifications in Appendix B.
Refer to Table 4-4, Rising Edge Trigger, Low Pulse with a Quadrature
Encoder Delay, for more information about fault conditions.
Cannot Drive Isolated Outputs
Verify that you have power connected to Viso and Ciso inputs on the
NI 1450 power connector and that the contact at the screw terminals is
solid. Because these outputs are electrically isolated from the NI 1450
main supply, they require power in addition to the NI 1450 main supply.
Runaway Startup Application
APP switch or the SAFE MODE switch in the ON position. Rebooting the
NI 1450 with the NO APP switch enabled prevents any VIs from running
at startup. Rebooting with the SAFE MODE switch enabled starts the
NI 1450 in Safe mode and does not launch the embedded LabVIEW RT
engine. Refer to the DIP Switches section of Chapter 3, LEDs, DIP
Switches, and Connectors, for more information about these DIP switches.
System Displays a MissingOperatingSystemError at Startup
The NI 1450 was powered on or reset with all DIP switches in the ON
by pressing the RESET button for at least two seconds.
LED Error Indications
The NI 1450 indicates specific error conditions by flashing the orange
STATUS LED a specific number of times. Table A-1 describes the
STATUS LED flashing sequences and the corresponding error condition.
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
Appendix A
Troubleshooting
Table A-1. STATUS LED Flashes and Corresponding Error Conditions
Number
of Flashes
Error Condition
0 (stays lit)
The NI 1450 has detected an internal error. Contact
National Instruments for assistance.
1
2
The NI 1450 is unconfigured.
The NI 1450 has detected an error in its software. This
usually occurs when an attempt to upgrade the firmware
is interrupted. Repeat the firmware upgrade process.
3
The NI 1450 is in Safe mode.
4 (or more) The NI 1450 has detected an unrecoverable error.
Contact National Instruments for assistance.
POWER OK LED Is Not Lit When the NI 1450 is
Powered on
If the power supply is properly connected to the NI 1450, but the POWER
OK LED does not light up, check that the power supply is 24 VDC 10%
and within the specifications outlined in Appendix B, Specifications. Using
a power supply that is not within these specifications might result in an
unresponsive or unstable system and could damage the NI 1450.
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B
Specifications
This appendix lists the specifications of the NI 1450 Series Compact Vision
System. These specifications are typical at 25 °C, unless otherwise noted.
Power Requirements
Main supply voltage............................... 24 VDC 10%
Power (excluding cameras)............. 12 W, typical
22 W, maximum
1394 bus power............................... 18 W, maximum
(shared by all three ports)
Isolated supply1 ...................................... 5 to 30 VDC
Memory
Network
SDRAM ................................................. 128 MB
Nonvolatile storage ................................ 32 MB
Network interface................................... 10BaseT and 100BaseTX
Ethernet
Compatibility ......................................... IEEE802.3
Communication rates ............................. 10 Mbps, 100 Mbps,
auto-negotiated
Maximum cabling distance .................... 100 m/segment
1
Do not draw more than 500 mA combined from the Viso pins on the 44-pin DSUB connector. Do not draw more than 100 mA
from each isolated output.
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
Appendix B
Specifications
TTL Inputs and Outputs
Digital logic levels
Level
Minimum
0 V
Maximum
0.5 V
5 V
Input low voltage (VIL)
Input high voltage (VIH)
2.2 V
2.4 V
—
Output low voltage (VOL), at 5 mA
Output high voltage (VOH), at 5 mA
—
0.4 V
TTL Inputs
Number of channels................................2
Maximum pulse rate ...............................2 MHz
Minimum pulse detected ........................200 ns
TTL Outputs
Number of channels................................10
Output voltage range ..............................0 V to 5 V
Maximum pulse rate ...............................2 MHz
Optically Isolated Inputs and Outputs
Isolated (Current Sinking) Inputs
Number of channels................................13
Input voltage range .................................0 V to 30 V
Input ON voltage.............................3.5 V to 30 V
Input OFF voltage............................0 V to 2 V
Turn-on current.......................................4 mA, typical;
7.1 mA, minimum;
14 mA, maximum
(current limited)
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Appendix B
Specifications
Maximum pulse rate............................... 100 kHz
Minimum pulse detected........................ 10 µs
Reverse polarity protection .................... yes
Isolated (Current Sourcing) Outputs
Number of channels ............................... 4
On-state voltage range ........................... 5 V to 30 V, maximum
Maximum on-state voltage
drop from Viso................................ 1.2 V at 100 mA
Output current ........................................ 100 mA, maximum
Maximum pulse rate............................... 10 kHz (maximum load resistance
100 kΩ)
Minimum pulse generated...................... 100 µs
Reverse polarity protection .................... Yes
IEEE 1394
Number of ports ..................................... 3
Speed...................................................... 100, 200, or 400 Mbps
Available bus power............................... Refer to the Power Requirements
section
Physical Characteristics
Dimensions............................................. 10.2 × 12.7 × 6.4 cm
(4 × 5 × 2.5 in.)
Weight.................................................... 977 g (2 lbs 2.4 oz)
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
Appendix B
Specifications
Environmental
The NI 1450 is intended for indoor use only.
Operating temperature,
vertical mounting position......................0 to 55 °C
Operating temperature,
all other positions....................................0 to 45 °C
Storage temperature................................–55 to 85 °C
Humidity.................................................10 to 90% RH, noncondensing
Pollution Degree.....................................2
Safety
The NI 1450 Series Compact Vision System 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 3121-1, UL 61010C-1
CAN/CSA C22.2 No. 1010.1
Note For UL and other safety certifications, refer to the product label or visit ni.com.
Electromagnetic Compatibility
Emissions................................................EN 55011 Class A at 10 m
FCC Part 15A above 1 GHz
Immunity ................................................EN 61326:1997 + A2:2001,
Table 1
EMC/EMI ...............................................CE, C-Tick, and FCC Part 15
(Class A) Compliant
Note For full EMC compliance, you must operate this device with shielded cabling.
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Appendix B
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, click Declarations
of Conformity Information at ni.com/hardref.nsf/. This Web site lists the DoCs by
product family. Select the appropriate product family, followed by your product, and a link
appears to the DoC in Adobe Acrobat format. Click the Acrobat icon to download or read
the DoC.
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
C
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 include the following:
–
Self-Help Resources—For immediate answers and solutions,
visit our extensive library of technical support resources available
in English, Japanese, and Spanish at ni.com/support. These
resources are available for most products at no cost to registered
users and include software drivers and updates, a KnowledgeBase,
product manuals, step-by-step troubleshooting wizards,
conformity documentation, example code, tutorials and
application notes, instrument drivers, discussion forums,
a measurement glossary, and so on.
–
Assisted Support Options—Contact NI engineers and other
measurement and automation professionals by visiting
ni.com/ask. Our online system helps you define your question
and connects you to the experts by phone, discussion forum,
or email.
•
•
Training—Visit ni.com/trainingfor self-paced tutorials, videos,
and interactive CDs. 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.
•
Declaration of Conformity (DoC)—A DoC is our claim of
compliance with the Council of the European Communities using the
manufacturer’s declaration of conformity. This system affords the user
protection for electronic compatibility (EMC) and product safety. You
can obtain the DoC for your product by visiting
ni.com/hardref.nsf.
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
Appendix C
Technical Support and Professional Services
•
Calibration Certificate—If your product supports calibration, you
can obtain the calibration certificate for your product at
ni.com/calibration.
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.
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Glossary
Symbol
Prefix
micro
milli
Value
10–6
10–3
103
µ
m
k
kilo
M
mega
106
Symbols
°C
Degrees Celsius.
A
AC
Alternating current.
acquisition window
The image size specific to a video standard or camera resolution.
B
b
Bits.
B
Bytes.
buffer
Temporary storage for acquired data.
D
DAQ
Data acquisition. (1) Collecting and measuring electrical signals from
sensors, transducers, and test probes or fixtures and inputting them to a
computer for processing; (2) Collecting and measuring the same kinds of
electrical signals with A/D or DIO boards plugged into a computer, and
possibly generating control signals with D/A and/or DIO boards in the
same computer.
DC
Direct current.
DCAM-compliant
Cameras that comply with the IIDC 1394-based Digital Camera
Specification, Version 1.30.
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
Glossary
DIP switch
DNS
Dual Inline Package switch.
Domain Name System.
E
Ethernet crossover cable Category 5 or Category 6 cable used for direct connection between the
development computer and the Real-Time target.
Ethernet cable, standard Category 5 or Category 6 Ethernet cable used to connect a Real-Time target
to a network port.
F
FTP
File Transfer Protocol.
H
Hz
Hertz. Frequency in units of one cycle per second.
Institute of Electrical and Electronics Engineers. A standard-setting body.
I
IEEE
interrupt
A computer signal indicating that the CPU should suspend its current task
to service a designated activity.
interrupt level
The relative priority at which a device can interrupt.
Input/Output.
I/O
IRQ
Interrupt request. See interrupt.
L
LED
Light-emitting diode.
M
m
Meters.
MAC
Media access control. The MAC address uniquely identifies each unit
connected to a network.
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Glossary
N
NI-IMAQ
Driver software for National Instruments image acquisition (IMAQ)
hardware.
P
PG
Pulse Generation.
PLC
Programmable Logic Controller. An industrial computer used for factory
automation, process control, and manufacturing systems.
POST
Power-On Self Test.
R
ROI
Region of interest. A hardware-programmable rectangular portion of the
acquisition window.
RS-232
Standard electrical interface for serial data communications.
S
subnet
A set of systems whose IP addresses are configured such that they can
communicate directly with one another. Data will not flow through an
intermediate router.
T
TCP
Transmission Control Protocol. A set of standard protocols for
communicating across a single network or interconnected set of networks.
TCP is for high-reliability transmissions.
U
UDP
User Datagram Protocol. A set of standard protocols for communicating
across a single network or interconnected set of networks. UDP is for
low-overhead transmissions.
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
Glossary
V
V
Volts.
VDC
VI
Volts direct current.
Virtual Instrument. A combination of hardware and/or software elements,
typically used with a PC, that has the functionality of a classic stand-alone
instrument.
W
W
Watts.
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Index
IEEE 1394, 3-8
SMB, 3-6
TRIG 0, 3-11
Numerics
100 Mbps LED, 3-2
TRIG 1, 3-11
TRIG 2, 3-11
VGA, 3-8
A
accessories, 2-2
contacting National Instruments, C-2
conventions used in the manual, v
customer
application software
installing LabVIEW, 2-15
installing Vision Builder AI, 2-13
installing Vision Development
Module, 2-15
professional services, C-1
technical support, C-1
B
bandwidth, available (table), 1-3
DCAM specification, 1-1, G-1
Declaration of Conformity, C-1
deployment, 5-1
C
cables
development computer
crossover, 2-3
digital I/O, 2-2
Ethernet crossover, 2-2
Ethernet standard, 2-2
SMB to BNC, 2-3
connecting to NI 1450, 2-12
connecting to NI 1450 system, 2-11
installing application software, 2-13
installing LabVIEW, 2-15
installing Vision Development
Module, 2-15
characteristic impedance, 4-14
calibration certificate, C-2
camera
available bandwidth, 1-3
connecting to the NI 1450, 2-8
digital camera specification, 1-1
video formats, 1-3
COM1, connector signals, 3-10
connecting multiple systems
subnet, 5-2
diagnostic resources, C-1
digital camera specification, 1-1
digital I/O
44-pin DSUB, 3-11
cable, D44, 3-11
connection considerations, 4-11
connector (table), 3-6
connector pinout (diagram), 3-12
connector signals (table), 3-12
examples (LabVIEW RT), 4-1
external load, wiring, 4-12
general-purpose, 3-11
connectors, 3-6
COM1, 3-10
Ethernet, 3-11
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
Index
isolated I/O, 4-2
isolated I/O (table), 4-3
protecting inductive loads, 4-13
signal functionality, 4-1
sourcing output device, wiring, 4-11
sourcing output device, wiring
(diagram), 4-12
flyback voltage, flyback diode, 4-13
frequently asked questions, C-1
transmission line effects, 4-13
TTL, 4-2
DIP switches
IP RESET, 3-5
location, 3-4
accessories, 2-2
NO APP, 3-5
overview, 3-3
SAFE MODE, 3-4
connecting a camera, 2-8
connecting the NI 1450 to the develpment
computer, 2-11
documentation
hardware, 2-3
LabVIEW RT, 2-3
online library, C-1
overview, 2-6
Vision Builder AI, 2-3
Vision Development Module, 2-3
required items, 2-1
subnets, 2-8
drivers
help
instrument, C-1
software, C-1
professional services, C-1
technical support, C-1
E
I
electromagnetic compatibility
specifications, B-4
environmental specifications, B-4
error indications (table), A-3
Ethernet
IEEE 1394
cable, 2-1
connector, 3-8
licensing, 1-1
IEEE 1394 bus, available power, B-1
IEEE 1394 camera
connecting to NI 1450, 2-8
digital camera specification, 1-1
IEEE 1394a (table), 3-6
image acquisition
connecting NI 1450
diagram, 2-12
connector, 3-11
crossover cable, 2-3
LINK LED, 3-2
port (table), 3-6
example code, C-1
external load, wiring, 4-12
LabVIEW RT, 2-17
Vision Builder AI, 2-14
inductive loads, protecting, 4-13
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Index
inputs
general-purpose, 4-8
National Instruments
calibration certificate, C-2
customer education, C-1
Declaration of Conformity, C-1
professional services, C-1
system integration services, C-1
technical support, C-1
worldwide offices, C-2
network
TTL, 4-2
installation category descriptions, 2-5
instrument drivers, C-1
IP address
configuring with Vision Builder AI, 2-13
configuring with Vision Development
Module, 2-16
IP RESET DIP switch, 3-5
isolated input, sourcing output device, 4-11
isolated output, external load, 4-11
connecting, 2-7
subnet, 2-8
network specifications, B-1
K
connecting multiple NI 1450 systems
(diagram), 5-1
KnowledgeBase, C-1
connecting to development
computer, 2-11
L
connectors (table), 3-6
DIP switches, overview, 3-3
IEEE 1394 connector, 3-8
optional hardware, 2-2
overview, 1-1
label, MAC address, serial number, 5-2
LabVIEW RT
acquiring images, 2-17
description, 1-5
installing, 2-15
parts locator, 1-2
LabVIEW, installing, 2-15
latch, 4-7
LEDs
NI-IMAQ for IEEE 1394 Cameras
driver software, 1-4
installing, 2-13
diagram, 3-1
POWER OK, 3-2
STATUS, 3-2
online technical support, C-1
outputs
M
MAC address, 5-2
general-purpose, 4-8
TTL, 4-2
MAX, 2-16
Measurement & Automation Explorer
(MAX), 2-16
media access control address, 5-2
memory, specifications, B-1
mounting kits, part numbers, 2-2
P
parts locator, 1-2
phone technical support, C-2
physical characteristic specifications, B-3
© National Instruments Corporation
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NI 1450 Series Compact Vision System User Manual
Index
POWER OK LED, 3-2
power requirements specifications, B-1
power supply
software
application, 1-4, 1-5
installing on development computer, 2-13
NI-IMAQ for IEEE 1394 Cameras, 1-4
software choices, 1-4
software drivers, C-1
sourcing output device
wiring, 4-11
connector, 3-6, 3-7
connector (table), 3-6
desktop, 2-1
earth ground, 3-7
separate main supply, 2-10
terminals (table), 3-7
wiring power, 2-9
diagram, 4-12
specifications
wiring power (diagram), 2-10
product selection port, 4-7
(table), 4-8
electromagnetic compatibility, B-4
environmental, B-4
memory, B-1
professional services, C-1
programming examples, C-1
pulse delay, 4-5
network, B-1
optically isolated inputs, B-2
optically isolated outputs, B-3
outputs, B-3
pulse modes, 4-5
pulse width, 4-5
physical characteristics, B-3
power requirements, B-1
safety, B-4
TTL inputs, B-2
TTL outputs, B-2
Q
quadrature encoder, 4-6
STATUS LED, 3-2
STATUS LED error indications (table), A-3
R
required hardware, 2-1
S
SAFE MODE DIP switch, 3-4
safety information, 2-4
safety specifications, B-4
serial number, 5-2
technical support, C-1
telephone technical support, C-2
termincal block, 37-pin (table), 3-12
timed pulse output, 4-4
timed pulse output, initiating, 4-4
training, customer, C-1
transmission line effects, 4-13
TRIG 0
serial port, connector (table), 3-6
setup
multiple NI 1450s, 5-1
typical single-camera, 4-14
setup and configuration, 2-1
shutdown, 4-9
cable, 3-11
connector (table), 3-6
shutdown, disabling, 4-10
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TRIG 1
cable, 3-11
connector (table), 3-6
TRIG 2
Vision Development Module
configuring IP address, 2-16
description, 1-5
installing, 2-15
cable, 3-11
connector (table), 3-6
trigger input lines, 4-3
trigger polarity, 4-5
troubleshooting
Web
professional services, C-1
technical support, C-1
worldwide technical support, C-2
hardware, A-2
software, A-1
STATUS LED error indications
(table), A-3
troubleshooting resources, C-1
V
VGA
connector (table), 3-6
connector signals (table), 3-9
VGA connector (diagram), 3-9
video formats, 1-3
Vision Builder AI
configuring IP address, 2-13
description, 1-5
image acquisition, 2-14
installing, 2-13
© National Instruments Corporation
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