National Instruments NI PCI-1426 User Manual

NI Vision

NI PCI-1426 User Manual

Base Configuration Camera Link Image Acquisition Device

NI PCI-1426 User Manual

February 2007
374040C-01

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Conventions

The following conventions are used in this manual:

<> Angle brackets that contain numbers separated by an ellipsis represent a

range of values associated with a bit or signal name—for example,
AO <3. .0>.

This icon denotes a note, which alerts you to important information.

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 parameter
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italic Italic text denotes variables, emphasis, a cross-reference, or an introduction

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variables, filenames, and extensions.

NI 1426 NI 1426 refers to the NI PCI-1426 image acquisition device.

Contents

Chapter 1
Introduction

Software Overview ........................................................................................................1-2

NI-IMAQ Driver Software ..............................................................................1-2

National Instruments Application Software ....................................................1-2

Integration with DAQ and Motion ..................................................................1-4

Camera Link ..................................................................................................................1-4

Overview .........................................................................................................1-4

Chapter 2
Hardware Overview

Functional Overview......................................................................................................2-1

Camera Link and the NI 1426 .........................................................................2-2

Data Transmission ...........................................................................................2-2

Hardware Binarization.....................................................................................2-3

Multiple-Tap Data Formatter ..........................................................................2-4

SDRAM...........................................................................................................2-4

Trigger Control and Mapping Circuitry ..........................................................2-4

Wiring an Isolated Input to Output Devices ....................................................2-5

Connecting to a Quadrature Encoder ..............................................................2-6

High-Speed Timing .........................................................................................2-7

Acquisition and Region of Interest (ROI) .......................................................2-7

Scatter-Gather DMA Controllers ....................................................................2-8

Bus Master PCI Interface ................................................................................2-8

Start Conditions ...............................................................................................2-8

Serial Interface.................................................................................................2-9

Vision Builder for Automated Inspection.........................................1-3

Vision Development Module ............................................................1-3

Base Configuration ...........................................................................2-2

Chapter 3
Signal Connections

Connectors .....................................................................................................................3-2

MDR 26-Pin Connector...................................................................................3-2

15-pin D-SUB Connector ................................................................................3-3

Connector Signal Connection Descriptions.....................................................3-4

© National Instruments Corporation vii NI PCI-1426 User Manual

Contents

Appendix A
Cabling

Appendix B
Technical Support and Professional Services

Glossary

Index

NI PCI-1426 User Manual viii ni.com

Introduction

The NI 1426 is an interface device that supports a diverse range of Camera
Link-compatible cameras. The NI 1426 acquires digital images in real time
and stores the images in onboard frame memory or transfers them directly
to system memory. Featuring a high-speed data flow path, the NI 1426 is
ideal for both industrial and scientific environments.

The NI 1426 is easy to install and configure. It ships with NI-IMAQ, the
National Instruments complete Vision driver software you can use to
directly control the NI 1426 and other National Instruments Vision
hardware products. With NI-IMAQ, you can quickly and easily start your
applications without having to program the device at the register level.

The NI 1426 supports the Camera Link Base configuration. The
MDR 26-pin connector provides access to base configuration cameras. For
further configuration information, refer to the Camera Link and the

NI 1426 section of Chapter 2, Hardware Overview.

The 15-pin D-SUB connector has four external TTL input/output (I/O)
lines you can use as triggers or as high-speed digital I/O lines. Should you
choose not to use the TTL I/O lines, the 15-pin D-SUB connector also
provides access to two optically isolated inputs and two RS-422 inputs.
These inputs can be individually selected in software.

1

For more advanced digital or analog system triggering or digital I/O lines,
you can use the NI 1426 and NI-IMAQ with the National Instruments data
acquisition (DAQ) or motion control product lines.

Synchronizing several functions to a common trigger or timing event can
be a challenge with image acquisition devices. The NI 1426 uses the
Real-Time System Integration (RTSI) bus to solve this problem.

The RTSI bus uses the National Instruments RTSI bus interface and ribbon
cable to route additional timing and trigger signals between the NI 1426
and up to four National Instruments DAQ, Motion Control, or image
acquisition devices.

For detailed specifications of the NI 1426, refer to the Specifications
section of Getting Started with the NI PCI-1426.

© National Instruments Corporation 1-1 NI PCI-1426 User Manual

Chapter 1 Introduction

Software Overview

Programming the NI 1426 requires the NI-IMAQ driver software for
controlling the hardware. National Instruments also offers the following
application software packages for analyzing and processing your acquired
images.

• Vision Builder for Automated Inspection—Allows you to configure

solutions to common inspection tasks.

• Vision Development Module—Provides customized control over

hardware and algorithms.

NI-IMAQ Driver Software

The NI-IMAQ driver software ships with the NI 1426. NI-IMAQ has an
extensive library of functions—such as routines for video configuration,
continuous and single shot image acquisition, memory buffer allocation,
trigger control, and device configuration—you can call from the
application development environment (ADE). NI-IMAQ handles many of
the complex issues between the computer and the image acquisition device,
such as programming interrupts and camera control.

NI-IMAQ performs all functions required for acquiring and saving images
but does not perform image analysis. Refer to the National Instruments
Application Software section for image analysis functionality.

NI-IMAQ is also the interface between the NI 1426 and LabVIEW,
LabWindows
NI-IMAQ software kit includes a series of libraries for image acquisition
for LabVIEW, LabWindows/CVI, and Measurement Studio, which
contains libraries for Microsoft Visual Basic.

NI-IMAQ features both high-level and low-level functions. Examples
of high-level functions include the sequences to acquire images in
multi-buffer, single-shot, or continuous mode. An example of a low-level
function is configuring an image sequence, since it requires advanced
understanding of the Vision device and image acquisition.

™

/CVI™, or a text-based programming environment. The

National Instruments Application Software

This section describes the National Instruments application software
packages you can use to analyze and process the images you acquire with
the NI 1426.

NI PCI-1426 User Manual 1-2 ni.com

Chapter 1 Introduction

Vision Builder for Automated Inspection

NI Vision Builder for Automated Inspection (AI) is configurable machine
vision software that you can use to prototype, benchmark, and deploy
applications. Vision Builder AI does not require programming, but is
scalable to powerful programming environments.

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. You also can migrate the configured inspection to
LabVIEW, extending the capabilities of the applications if necessary.

Vision Development Module

NI Vision Development Module, which consists of NI Vision and
NI Vision Assistant, is an image acquisition, processing, and analysis
library of more than 270 functions for the following common machine
vision tasks:

• Pattern matching

• Particle analysis

•Gauging

• Taking measurements

• Grayscale, color, and binary image display

You can use the Vision Development Module functions individually or
in combination. With the Vision Development Module, you can acquire,
display, and store images, as well as perform image analysis and
processing. Using the Vision Development Module, imaging novices and
experts can program the most basic or complicated image applications
without knowledge of particular algorithm implementations.

As a part of the Vision Development Module, NI Vision Assistant is an
interactive prototyping tool for machine vision and scientific imaging
developers. With Vision Assistant, you can prototype vision applications
quickly and test how various image processing functions work.

Vision Assistant generates a Builder file, which is a text description
containing a recipe of the machine vision and image processing functions.
This Builder file provides a guide you can use for developing applications
in any ADE, such as LabWindows/CVI or Visual Basic, using the Vision
Assistant machine vision and image processing libraries. Using the

© National Instruments Corporation 1-3 NI PCI-1426 User Manual

Chapter 1 Introduction

LabVIEW VI creation wizard, Vision Assistant can create LabVIEW VI
diagrams that perform the prototype you created in Vision Assistant.
You can then use LabVIEW to add functionality to the generated VI.

Integration with DAQ and Motion

Platforms that support NI-IMAQ also support NI-DAQ and a variety of
National Instruments DAQ devices. This allows integration between image
acquisition devices and National Instruments DAQ devices.

Use National Instruments high-performance stepper and servo motion
control products with pattern matching software in inspection and guidance
applications, such as locating alignment markers on semiconductor wafers,
guiding robotic arms, inspecting the quality of manufactured parts, and
locating cells.

Camera Link

This section provides a brief overview of the Camera Link standard. Refer
to the Specifications of the Camera Link Interface Standard for Digital
Cameras and Frame Grabbers manual for more detailed information about
Camera Link specifications. This manual is available on several Web sites,
including the Automated Imaging Association site at

www.machinevisiononline.org.

Overview

Developed by a consortium of camera and image acquisition device
manufacturers, Camera Link is a standard for interfacing digital cameras
with image acquisition devices. Camera Link simplifies connectivity
between the image acquisition device and the camera by defining a single
standard connector for both. This standard ensures physical compatibility
of devices bearing the Camera Link logo.

The basis for the Camera Link standard is the National Semiconductor
Channel Link chipset, a data transmission method consisting of a
general-purpose transmitter/receiver pair. The Channel Link driver takes
28 bits of parallel digital data and a clock and serializes the stream to
four LVDS (EIA-644) data streams and an LVDS clock, providing
high-speed data transmission across 10 wires and over distances of up
to 10 m.

NI PCI-1426 User Manual 1-4 ni.com

Hardware Overview

This chapter provides an overview of NI 1426 hardware functionality and
explains the operations of the NI 1426 functional units.

Functional Overview

The NI 1426 features a flexible, high-speed data path optimized for
receiving and formatting video data from Camera Link cameras.

Figure 2-1 illustrates the key functional components of the NI 1426.

2

Synchronous Dynamic RAM

Data

Enables

Pixel

Clock

Camera

Control

MDR 26-Pin Connector

Serial

Control

15-Pin D-SUB

© National Instruments Corporation 2-1 NI PCI-1426 User Manual

Channel

Link

Receiver

Differential

Converter

Pixel Clock and Camera Enables

External Triggers

Data

Advanced

Timing

UART

SDRAM

Interface

Acquisition,

ROI, and Triggering

Figure 2-1. NI 1426 Block Diagram

Data

PCI Interface

Scatter-Gather

DMA Controllers

RTSI Bus

and

PCI Bus

Chapter 2 Hardware Overview

Camera Link and the NI 1426

The NI 1426 supports the Camera Link Base configuration.

Base Configuration

The Camera Link Base configuration places 24 data bits and four enable
signals (Frame Valid, Line Valid, Data Valid, and a spare) on a single
Channel Link part and cable.

The Base configuration includes asynchronous serial transmission as well
as four digital camera control lines for controlling exposure time, frame
rates, and other camera control signals. These four control lines are
configured in the camera file to generate precise timing signals for
controlling digital camera acquisition.

Base configuration includes the following bit allocations:

•8-bit × 1, 2, and 3 taps (channels)

• 10-bit × 1 and 2 taps

• 12-bit × 1 and 2 taps

• 14-bit × 1 tap

• 16-bit × 1 tap

• 24-bit RGB

Data Transmission

A 28-to-4 serializing Channel Link chip drives the data and camera enable
signals across the Camera Link cable, and the camera’s pixel clock controls
the Channel Link’s data transmission. The four LVDS pairs are then
deserialized by another Channel Link chip on the NI 1426.

Note Exact timing of camera and image acquisition device communication is camera

dependent. Refer to the Specifications of the Camera Link Interface Standard for Digital
Cameras and Frame Grabbers manual for more information about Camera Link timing

requirements.

NI PCI-1426 User Manual 2-2 ni.com

Hardware Binarization

The NI 1426 supports binarization and inverse binarization. Binarization
and inverse binarization segment an image into two regions: a particle
region and a background region. Use binarization and inverse binarization
to isolate objects of interest in an image.

To separate objects under consideration from the background, select a pixel
value range. This pixel value range is known as the gray-level interval, or
the threshold interval. Binarization works by setting all image pixels that
fall within the threshold interval to the image white value and setting all
other image pixels to 0. Pixels inside the threshold interval are considered
part of the particle region. Pixels outside the threshold interval are
considered part of the background region.

Inverse binarization flips the assigned bit numbers of the particle region and
the background region. Thus, all pixels that belong in the threshold interval,
or the particle region, are set to 0, while all pixels outside the threshold
interval, or the background region, are set to the image white value.

Figure 2-2 illustrates binarization and inverse binarization.

Chapter 2 Hardware Overview

NORMAL

Stored Value

Sampled Data

Figure 2-2. Binarization and Inverse Binarization

© National Instruments Corporation 2-3 NI PCI-1426 User Manual

Stored Value

INVERSE

Sampled Data

Chapter 2 Hardware Overview

Multiple-Tap Data Formatter

Many digital cameras transfer multiple taps, or channels, of data
simultaneously to increase the frame rate of the camera. However, the data
in each tap may not be transferred in the traditional top-left to bottom-right
direction. Also, the taps may not transfer data in the same direction.

The multiple-tap data formatting circuitry on the NI 1426 can reorder the
data from up to three taps. The data from each tap can be independently
scanned either from left-to-right or right-to-left and top-to-bottom or
bottom-to-top.

Note For your convenience, data reformatting instructions for these cameras have been

preprogrammed into the camera files.

SDRAM

Depending on the memory option purchased, the NI 1426 has 16 MB or
32 MB of onboard high-speed synchronous dynamic RAM (SDRAM). The
NI 1426 uses the onboard RAM as a FIFO buffer to ensure a complete
acquisition. Even when the data rate from the camera exceeds PCI
throughput, you can acquire without interruption until the onboard RAM
is full.

Trigger Control and Mapping Circuitry

The trigger control and mapping circuitry routes, monitors, and drives
the external and RTSI bus trigger lines. You can configure each line to start
an acquisition on a rising or falling edge and drive each line asserted or
unasserted, much like a digital I/O line. You also can map pulses from the
high-speed timing circuitry or many of the NI 1426 status signals to these
trigger lines. Four RTSI bus triggers and four external triggers (all of
which are programmable for polarity and direction) are available for
simultaneous use.

Individually configure the four external triggers in Measurement and
Automation Explorer (MAX), the National Instruments Configuration
utility, as single-ended I/O lines or, alternatively, as isolated or RS-422
input only lines. You can configure the four external triggers in any
combination of single-ended I/O or input only lines. Table 2-1 lists the
configuration options available for each trigger source.

NI PCI-1426 User Manual 2-4 ni.com

Chapter 2 Hardware Overview

Table 2-1. Trigger Configuration Options for the NI 1426

Single-ended

Trigger Number

Input/Output

0 TTL_TRIG(0) ISO_IN(0)

1 TTL_TRIG(1) ISO_IN(1)

2 TTL_TRIG(2) RS422_IN(0)

3 TTL_TRIG(3) RS422_IN(1)

Note If not configured as single-ended I/O lines, triggers have input only capability.

Wiring an Isolated Input to Output Devices

You can wire an isolated input to both sourcing and sinking output devices.
Refer to Figures 2-3 and 2-4 for wiring examples by output type. Refer to
Getting Started with the NI PCI-1426 for information about switching
thresholds and current requirements.

Caution Do not apply a voltage greater than 30 VDC to the isolated inputs. Voltage greater

than 30 VDC may damage the NI 1426.

Note Isolated inputs are compatible with 5 V logic if the external circuit meets the voltage

and current requirements listed in Getting Started with the NI PCI-1426.

Alternative
Input Only

Sensor

Powe r

PNP (Sourcing)

Output Device

Sensor

Common

Figure 2-3. Example of Connecting an Isolated Input to a Sourcing Output Device

© National Instruments Corporation 2-5 NI PCI-1426 User Manual

IN

IN

+

–

NI 1426

Current

Limiter

Vcc

Chapter 2 Hardware Overview

NPN (Sinking)
Output Device

Sensor

Powe r

IN

IN

+

Current

Limiter

–

Vcc

Sensor

Common

Figure 2-4. Example of Connecting an Isolated Input to a Sinking Output Device

Connecting to a Quadrature Encoder

The NI 1426 accepts differential (RS-422) line driver inputs. Shielded
encoder cables are recommended for all applications. Unshielded cables
are more susceptible to noise and can corrupt the encoder signals. Refer to
Figure 2-5 for an example of connecting differential line drivers.

Encoder NI 1426

Phase A

Phase B

Twisted
Pair

Twisted
Pair

NI 1426

7

8

14

15

Phase A+

Phase A–Phase A–

Phase B+

Phase B–Phase B–

+

26LS32

–

+

26LS32

–

Figure 2-5. Example of Connecting Differential Line Drivers

NI PCI-1426 User Manual 2-6 ni.com

High-Speed Timing

Built from high-speed counters, the high-speed timing circuitry on the
NI 1426 can generate precise real-time control signals for your camera.
Map the output of this circuitry to a trigger line to provide accurate pulses
and pulse trains. Map these control signals to the camera control lines to
control exposure time and frame rate.

Note For your convenience, the external control for cameras that support the NI 1426 has

been preprogrammed into the camera file. You can use MAX to specify the frequency and
duration of these signals in easy-to-use units.

The NI 1426 also allows you to route the external trigger inputs 0–3 onto
the camera control lines 1–4. Use MAX to select the source for the camera
control lines. You have the option to choose either the default control signal
that is specified in the camera file or the external trigger input as the source
for the camera control lines.

Acquisition and Region of Interest (ROI)

The acquisition and ROI circuitry monitors incoming video signals and
routes the active pixels to the multiple-tap data formatter and SDRAM.
The NI 1426 can perform ROI acquisitions on all video lines and frames.
In an ROI acquisition, select an area within the acquisition window to
transfer across the PCI bus to system memory.

Chapter 2 Hardware Overview

Configure the following parameters on the NI 1426 to control the video
acquisition window:

• Acquisition window—The NI 1426 allows the user to specify a

particular region of active pixels and active lines within the incoming
video data. The active pixel region selects the starting pixel and
number of pixels to be acquired relative to the assertion edge of the
horizontal (or line) enable signal from the camera. The active line
region selects the starting line and number of lines to be acquired
relative to the assertion edge of the vertical (or frame) enable signal.

• Region of interest—The NI 1426 uses a second level of active pixel

and active line regions for selecting a region of interest. Using the
region-of-interest circuitry, the device acquires only a selected subset
of the acquisition window.

Note You can use MAX to set the acquisition window on the NI 1426.

© National Instruments Corporation 2-7 NI PCI-1426 User Manual

Chapter 2 Hardware Overview

Scatter-Gather DMA Controllers

The NI 1426 uses three independent onboard direct memory access (DMA)
controllers. The DMA controllers transfer data between the onboard
SDRAM memory buffers and the PCI bus. Each of these controllers
supports scatter-gather DMA, which allows the DMA controller to
reconfigure on-the-fly. The NI 1426 can perform continuous image
transfers directly to either contiguous or fragmented memory buffers.

Bus Master PCI Interface

The NI 1426 implements the PCI interface with a National Instruments
custom application-specific integrated circuit (ASIC), the PCI miniMITE.
The PCI interface can transfer data at a theoretical maximum rate of
133 MB/s in bus master mode.

Start Conditions

The NI 1426 can start acquisitions in the following ways:

• Software control—The NI 1426 supports software control of a start

acquisition. You can configure the NI 1426 to capture a fixed number
of frames. This configuration is useful for capturing a single frame or
a sequence of frames.

• Trigger control—You can start an acquisition by enabling external

or RTSI bus trigger lines. Each of these inputs can start a video
acquisition on a rising or falling edge. You can use all four external
triggers and up to four RTSI bus triggers simultaneously.

• Delayed acquisition—Use either software or triggers to start

acquisitions instantaneously or after skipping a specific number of
frames. You can use delayed acquisition for post-trigger applications.

NI PCI-1426 User Manual 2-8 ni.com

Serial Interface

Chapter 2 Hardware Overview

The NI 1426 provides serial connections to and from the camera through
two LVDS pairs in the Camera Link cable. All Camera Link serial
communication uses one start bit, one stop bit, no parity, and no hardware
handshaking.

The NI 1426 supports the following baud rates: 56000, 38400, 19200,
9600, 7200, 4800, 3600, 2400, 2000, 1800, 1200, 600, and 300 bps.

You can use the serial interface interactively with MAX and

clsercon.exe, or programmatically with LabVIEW and C.

Interactively:

• MAX—Use MAX with a camera file containing preprogrammed

commands. When an acquisition is initiated, the commands are sent to
the camera.

•

clsercon.exe—Use the National Instruments terminal emulator for

Camera Link,

clsercon.exe, if a camera file with preprogrammed

serial commands does not exist for your camera. With

clsercon.exe, you can still communicate serially with your

camera. Go to

<NI-IMAQ>\bin to access clsercon.exe.

Programmatically:

• LabVIEW—Use the serial interface programmatically, through calls

to the NI-IMAQ driver using the IMAQ Serial Write and IMAQ Serial
Read VIs. Go to

imaqll.llb

<LabVIEW>\vi.lib\vision\driver\

to access these files.

• C—Use the serial interface programmatically, through calls to the

NI-IMAQ driver using

imgSessionSerialRead.

Note IMAQ Serial Read, IMAQ Serial Write, clsercon.exe,
imgSessionSerialRead, and imgSessionSerialWrite are used for directly

imgSessionSerialWrite and

accessing the NI 1426 serial port and are not required for most users.

National Instruments also fully supports the recommended serial API
described in the Specifications of the Camera Link Interface Standard for
Digital Cameras and Frame Grabbers manual. This manual is available on
several websites, including the Automated Image Association Web site at

www.machinevisiononline.org.

© National Instruments Corporation 2-9 NI PCI-1426 User Manual

Signal Connections

Figure 3-1 shows the connectors on the front panel of the NI 1426.

3

1

CAMERA LINK

2

TRIGGERS

1 MDR 26-Pin Connector 2 15-Pin D-SUB Connector

Figure 3-1. NI 1426 Connectors

© National Instruments Corporation 3-1 NI PCI-1426 User Manual

Chapter 3 Signal Connections

Connectors

This section describes the MDR 26-pin connector and the 15-pin D-SUB
connector on the NI 1426.

MDR 26-Pin Connector

The MDR 26-pin connector provides reliable high-frequency transfer rates
between the camera and the acquisition device. To access this connector,
use a 3M Camera Link cable. Refer to the Camera Link Cables section of
Appendix A, Cabling, for additional information about Camera Link
cables, including available cable lengths and ordering information.

Figure 3-2 shows the NI 1426 MDR 26-pin connector assignments. Refer
to Table 3-1 for a description of the MDR 26-pin and 15-pin D-SUB signal
connections.

DGND
CC(4)+
CC(3)–
CC(2)+
CC(1)–

SerTFG–

SerTC+

X(3)–

XCLK–

X(2)–
X(1)–
X(0)–

DGND

14
15
16
17
18
19
20
21
22
23
24
25
26

1
2
3
4
5
6
7
8

9
10
11
12
13

DGND
CC(4)–
CC(3)+
CC(2)–
CC(1)+
SerTFG+
SerTC–
X(3)+
XCLK+
X(2)+
X(1)+
X(0)+
DGND

Figure 3-2. MDR 26-Pin Connector Assignments

NI PCI-1426 User Manual 3-2 ni.com

15-pin D-SUB Connector

The 15-pin D-SUB connector connects to general purpose digital I/O. The
general purpose digital I/O available on this connector includes four TTL
I/O lines, two optically isolated input lines, and two RS-422 input lines.

National Instruments provides a generic 15-pin cable assembly kit
(part number 190912-04) that breaks the connector out into 15 color-coded
wires for easy connectivity. Refer to the 15-Pin D-SUB Cable

Specifications section of Appendix A, Cabling, for information about

ordering a cable assembly kit.

If you require twisted pair wiring, you must build a custom cable. Refer to
the connector pin assignments in Figure 3-3 and the 15-Pin D-SUB Cable

Specifications section of Appendix A, Cabling, to build a custom cable for

the 15-pin D-SUB connector.

Chapter 3 Signal Connections

TTL_TRIG(0)

TTL_TRIG(1)

TTL_TRIG(2)

TTL_TRIG(3)

ISO_IN(0)+
ISO_IN(0)–
PHASE_A+
PHASE_A–

1

9

10

11

12

13

14

15

DGND
DGND
DGND
ISO_IN(1)+
ISO_IN(1)–
PHASE_B+
PHASE_B–

2

3

4

5

6

7

8

Figure 3-3. 15-Pin D-SUB Connector Pin Assignments

© National Instruments Corporation 3-3 NI PCI-1426 User Manual

Chapter 3 Signal Connections

Connector Signal Connection Descriptions

Table 3-1 describes the MDR 26-pin and 15-pin D-SUB signal
connections.

Table 3-1. I/O Connector Signals

Signal Name Description

TTL_TRIG<3..0> TTL external triggers/DIO lines (I/O).

DGND Direct connection to digital GND on the NI 1426.

ISO_IN<1..0>± 30 V isolated input only lines.

Use these lines instead of, not in addition to, TTL_TRIG<1..0>.

PHASE_A±

PHASE_B±

The primary use of these signals is for interfacing to a quadrature encoder.

Alternatively, these pairs can be used as independent RS-422 trigger inputs
instead of, not in addition to, TTL_TRIG<3..2>.

X<3..0>± LVDS Base configuration data and enable signals from the camera to the

acquisition device.

XCLK± Transmission clock on the Base configuration chip for Camera Link

communication between the acquisition device and the camera.

SerTC± Serial transmission to the camera from the image acquisition device.

SerTFG± Serial transmission to the frame grabber from the camera.

CC<4..1>± Four LVDS pairs, defined as camera inputs and acquisition device outputs,

reserved for camera control.

On some cameras, the camera controls allow the acquisition device to control
exposure time and frame rate.

NI PCI-1426 User Manual 3-4 ni.com

Cabling

This appendix contains cabling requirements for the NI 1426, including
Camera Link cable ordering information.

15-Pin D-SUB Cable Specifications

National Instruments provides a generic 15-pin cable assembly kit
(part number 190912-04) that breaks the connector out into 15 color-coded
wires for easy connectivity. Visit the National Instruments Web site at

ni.com/catalog to purchase a cable assembly kit for the NI 1426.

If you decide to build a custom cable, National Instruments recommends
that you use twisted pair wiring to help reduce noise pickup from outside
sources and crosstalk. TTL I/O lines should be twisted together with a wire
connected to DGND. Isolated input and RS-422 input lines should be
twisted together in their proper +/– pairs.

Refer to the Connectors section of Chapter 3, Signal Connections, for
connector pin assignments.

A

Camera Link Cables

Use a standard Camera Link cable to connect your camera to the MDR
26-pin connector on the NI 1426. Camera Link cables consist of two MDR
26-pin male plugs linked with a twin-axial shielded cable and are available
in two shell configurations.

Note National Instruments recommends purchasing a Camera Link cable. Building your

own cable is not recommended due to the high-speed signaling on the Camera Link
interface.

Refer to the Specifications of the Camera Link Interface Standard for
Digital Cameras and Frame Grabbers manual for more information about
Camera Link cables.

© National Instruments Corporation A-1 NI PCI-1426 User Manual

Appendix A Cabling

Figure A-1 illustrates the Camera Link cable.

Ordering Information

Camera Link cables are manufactured by 3M corporation and are available
from both National Instruments and 3M.

1

2

1 MDR 26-Pin Male Plug 2 2X Thumbscrews

Figure A-1. Camera Link Cable

Two-meter Camera Link cables (part number 187676-02) are available
from the National Instruments Web site at

ni.com/catalog. Camera

Link cables are available in 1 to 10 m lengths from the 3M Web site at

www.3m.com. Refer to Figure A-2 for 3M part number information.

14X26-SZLB-XXX-0LC

Shell Retention Options:

B = Thumbscrew shell kit
T = Thumbscrew overmold shell

Figure A-2. 3M Part Number Ordering Information

NI PCI-1426 User Manual A-2 ni.com

Length:

100 = 1 meter
200 = 2 meters
300 = 3 meters
450 = 4.5 meters
500 = 5 meters
700 = 7 meters
A00 = 10 meters

Technical Support and
Professional Services

Visit the following sections of the National Instruments Web site at

ni.com for technical support and professional services:

• Support—Online technical support resources at

include the following:

– Self-Help Resources—For answers and solutions, visit the

award-winning National Instruments Web site for software drivers
and updates, a searchable KnowledgeBase, product manuals,
step-by-step troubleshooting wizards, thousands of example
programs, tutorials, application notes, instrument drivers, and
so on.

– Free Technical Support—All registered users receive free Basic

Service, which includes access to hundreds of Application
Engineers worldwide in the NI Discussion Forums at

ni.com/forums. National Instruments Application Engineers

make sure every question receives an answer.

For information about other technical support options in your
area, visit

ni.com/contact.

• Training and Certification—Visit

self-paced training, eLearning virtual classrooms, interactive CDs,
and Certification program information. You also can register for
instructor-led, hands-on courses at locations around the world.

• System Integration—If you have time constraints, limited in-house

technical resources, or other project challenges, National Instruments
Alliance Partner members can help. To learn more, call your local
NI office or visit

• 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/certification.

ni.com/services or contact your local office at

ni.com/alliance.

B

ni.com/support

ni.com/training for

© National Instruments Corporation B-1 NI PCI-1426 User Manual

Appendix B 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.com and 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/niglobal to access the branch

office Web sites, which provide up-to-date contact information, support
phone numbers, email addresses, and current events.

NI PCI-1426 User Manual B-2 ni.com

Glossary

A

acquisition window The image size specific to a video standard or camera resolution.

active line region The region of lines actively being stored. Defined by a line start (relative to

the vertical synchronization signal) and a line count.

active pixel region The region of pixels actively being stored. Defined by a pixel start (relative

to the horizontal synchronization signal) and a pixel count.

API Application programming interface.

area A rectangular portion of an acquisition window or frame that is controlled

and defined by software.

ASIC Application-Specific Integrated Circuit. A proprietary semiconductor

component designed and manufactured to perform a set of specific
functions for specific customer needs.

B

buffer Temporary storage for acquired data.

bus A group of conductors that interconnect individual circuitry in a computer,

such as the PCI bus; typically the expansion vehicle to which I/O or other
devices are connected.

C

Camera Link Interface standard for digital video data and camera control based on the

Channel Link chipset.

Channel Link National Semiconductor chipset for high-speed data serialization and

deserialization for transmission across cables up to 10 m.

© National Instruments Corporation G-1 NI PCI-1426 User Manual

Glossary

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.

DMA Direct memory access. A method by which data can be transferred to and

from computer memory from and to a device or memory on the bus while
the processor does something else; DMA is the fastest method of
transferring data to/from computer memory.

F

FIFO First-in first-out memory buffer. The first data stored is the first data sent

to the acceptor; FIFOs are used on Vision devices to temporarily store
incoming data until that data can be retrieved.

L

LVDS Low Voltage Differential Signaling (EIA-644).

N

NI-IMAQ Driver software for National Instruments Vision hardware.

P

PCI Peripheral Component Interconnect. A high-performance expansion bus

architecture originally developed by Intel to replace ISA and EISA. PCI
offers a theoretical maximum transfer rate of 133 Mbytes/s.

pixel Picture element. The smallest division that makes up the video scan line;

for display on a computer monitor, a pixel’s optimum dimension is square
(aspect ratio of 1:1, or the width equal to the height).

pixel clock Divides the incoming horizontal video line into pixels.

NI PCI-1426 User Manual G-2 ni.com

Glossary

Q

quadrature encoder A device that converts angular rotation into two pulse trains, A and B. The

phase difference between A and B transmits information about the
direction of rotation and the number of transitions indicates the amount of
rotation.

R

real time A property of an event or system in which data is processed as it is acquired

instead of being accumulated and processed at a later time.

resolution The smallest signal increment that can be detected by a measurement

system. Resolution can be expressed in bits, in proportions, or in
percent of full scale. For example, a system has 12-bit resolution,
one part in 4,096 resolution, and 0.0244 percent of full scale.

RGB Color encoding scheme using red, green, and blue (RGB) color information

where each pixel in the color image is encoded using 32 bits: eight bits for
red, eight bits for green, eight bits for blue, and eight bits for the alpha value
(unused).

ROI Region of interest. A hardware-programmable rectangular portion of the

acquisition window.

RTSI bus Real-Time System Integration Bus. The National Instruments timing bus

that connects image acquisition and DAQ devices directly, by means of
connectors on the devices, for precise synchronization of functions.

S

scatter-gather DMA A type of DMA that allows the DMA controller to reconfigure on-the-fly.

SDRAM Synchronous dynamic RAM.

© National Instruments Corporation G-3 NI PCI-1426 User Manual

Glossary

T

tap A stream of pixels from a camera. Some cameras send multiple streams,

or taps, of data over a cable simultaneously to increase transfer rate.

transfer rate The rate, measured in bytes/s, at which data is moved from source to

destination after software initialization and set up operations. The
maximum rate at which the hardware can operate.

trigger Any event that causes or starts some form of data capture.

trigger control and
mapping circuitry

TTL Transistor-transistor logic.

Circuitry that routes, monitors, and drives external and RTSI bus trigger
lines. You can configure each of these lines to start or stop acquisition on a
rising or falling edge.

V

VI Virtual Instrument. (1) A combination of hardware and/or software

elements, typically used with a PC, that has the functionality of a classic
stand-alone instrument. (2) A LabVIEW software module (VI), which
consists of a front panel user interface and a block diagram program.

NI PCI-1426 User Manual G-4 ni.com

Index

Numerics

15-pin D-SUB connector, 3-3

cable specifications, A-1
overview, 3-3
pin assignments (figure), 3-3

A

acquisition and region of interest (ROI)

circuitry, 2-7
acquisition start conditions, 2-8
acquisition window control

active pixel region (acquisition

window), 2-7

region of interest, 2-7

B

Base configuration, Camera Link, 2-2
block diagram of NI 1426 (figure), 2-1
bus master PCI interface, 2-8

C

cabling

15-pin D-SUB connector, A-1
Camera Link cable (figure), A-2

Camera Link cables, A-1
calibration certificate (NI resources), B-2
Camera Link

Base configuration, 2-2

cabling

description, A-1
ordering information, A-2

overview, 1-4
CC<4..1>± signal (table), 3-4
clock signals, XCLK± signal (table), 3-4

configuration, Camera Link

Base configuration, 2-2

connectors

15-pin D-SUB connector, 3-3
I/O connector signals (table), 3-4
MDR 26-pin connector (figure), 3-2
NI 1426 connectors (figure), 3-1
signal description (table), 2-5, 3-4

conventions used in manual, v

D

data formatter, multiple tap, 2-3, 2-4
data transmission, 2-2
Declaration of Conformity (NI resources), B-1
delayed acquisition start conditions, 2-8
DGND signal (table), 3-4
diagnostic tools (NI resources), B-1
DMA controllers, 2-8
documentation

conventions used in the manual, v

NI resources, B-1
drivers (NI resources), B-1
D-SUB connector, 15-pin, 3-3

cable specifications, A-1

overview, 3-3

pin assignments (figure), 3-3

E

examples (NI resources), B-1

H

hardware overview, 2-1

acquisition, region of interest (ROI), 2-7

binarization, 2-3

block diagram (figure), 2-1

© National Instruments Corporation I-1 NI PCI-1426 User Manual

Index

bus master PCI interface, 2-8
Camera Link, Base configuration, 2-2
data transmission, 2-2
high-speed timing, 2-7
multiple-tap data formatter, 2-4
scatter-gather DMA controllers, 2-8
SDRAM, 2-4
serial interface, 2-9
start conditions, 2-8
trigger control and mapping circuitry, 2-4
wiring an isolated input to a

sourcing/sinking output device, 2-5

wiring an isolated input to output

devices, 2-5
help, technical support, B-1
high-speed timing circuitry, 2-5, 2-7

I

I/O connector. See connectors
installation, cabling

15-pin D-SUB cable specifications, A-1

Camera Link cables, A-1
instrument drivers (NI resources), B-1
integration with DAQ and motion control, 1-4
ISO_IN± signal (table), 3-4

K

KnowledgeBase, B-1

N

National Instruments

application software, 1-2
support and services, B-1

NI 1426

Camera Link, 1-4
software programming choices, 1-2

integration with DAQ, 1-4
National Instruments application

software, 1-2

NI Vision Builder for Automated

Inspection, 1-3
NI Vision Development Module, 1-3
NI-IMAQ driver software, 1-2

NI support and services, B-1
NI Vision Assistant, 1-3
NI-IMAQ driver software, 1-2

P

PHASE_A± signal (table), 3-4
PHASE_B± signal (table), 3-4
programming examples (NI resources), B-1

Q

quadrature encoder

connecting to, 2-6
signal descriptions, 3-4

L

LabVIEW, Vision Builder AI, 1-3

M

mapping circuitry, 2-4
MDR 26-pin connector, 3-2
multiple-tap data formatter, 2-3, 2-4

NI PCI-1426 User Manual I-2 ni.com

R

Real-Time System Integration (RTSI) bus, 1-1
region of interest (ROI) circuitry, 2-7
region of interest, in acquisition window

control, 2-7

Index

S

scatter-gather DMA controllers, 2-8
SDRAM, 2-4
serial interface, 2-9
SerTC± signal (table), 3-4
SerTFG± signal (table), 3-4
signal connections

connectors

15-pin D-SUB connector, 3-3
MDR 26-pin connector, 3-2
NI 1426 connectors (figure), 3-1

signal descriptions, 3-4
software (NI resources), B-1
software controlled start conditions, 2-8
software programming choices, 1-2

integration with DAQ, 1-4
NI Vision Builder for Automated

Inspection, 1-3
NI Vision Development Module, 1-3
NI-IMAQ driver software, 1-2

start conditions

delayed acquisition, 2-8
software control, 2-8
trigger control, 2-8

support, technical, B-1

T

technical support, B-1
timing circuitry, high-speed, 2-7
training and certification (NI resources), B-1
trigger

configuration options (table), 2-5
control and mapping circuitry, 2-4

controlled start conditions, 2-8
troubleshooting (NI resources), B-1
TTL_TRIG signal (table), 3-4

W

Web resources, B-1

X

X<3..0>± signal (table), 3-4
XCLK± signal (table), 3-4

© National Instruments Corporation I-3 NI PCI-1426 User Manual