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VXI-MIO Series
User Manual
Multifunction I/O Modules for VXIbus
August 1996 Edition
Part Number 321246A-01
Copyright 1996 National Instruments Corporation. All Rights Reserved.
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Important Information
Warranty
The VXI-MIO Series boards are 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.
The media on which you receive National Instruments software are warranted not to fail to execute programming
instructions, due to defects in materials and workmanship, for a period of 90 days from date of shipment, as evidenced
by receipts or other documentation. National Instruments will, at its option, repair or replace software media that do
not execute programming instructions if National Instruments receives notice of such defects during the warranty
period. National Instruments does not warrant that the operation of the software shall be uninterrupted or error free.
A Return Material Authorization (RMA) number must be obtained from the factory and clearly marked on the outside
of the package before any equipment will be accepted for warranty work. National Instruments will pay the shipping
costs of returning to the owner parts which are covered by warranty.
National Instruments believes that the information in this manual is accurate. The document has been carefully
reviewed for technical accuracy. In the event that technical or typographical errors exist, National Instruments
reserves the right to make changes to subsequent editions of this document without prior notice to holders of this
edition. The reader should consult National Instruments if errors are suspected. In no event shall National
Instruments be liable for any damages arising out of or related to this document or the information contained in it.
EXCEPT AS SPECIFIED HEREIN, NATIONAL INSTRUMENTS MAKES NO WARRANTIES, EXPRESS OR IMPLIED, AND
SPECIFICALLY DISCLAIMS ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
CUSTOMER’S RIGHT TO RECOVER DAMAGES CAUSED BY FAULT OR NEGLIGENCE ON THE PART OF NATIONAL
INSTRUMENTS SHALL BE LIMITED TO THE AMOUNT THERETOFORE PAID BY THE CUSTOMER. NATIONAL INSTRUMENTS
WILL NOT BE LIABLE FOR DAMAGES RESULTING FROM LOSS OF DATA, PROFITS, USE OF PRODUCTS, OR INCIDENTAL OR
CONSEQUENTIAL DAMAGES, EVEN IF ADVISED OF THE POSSIBILITY THEREOF. This limitation of the liability of National
Instruments will apply regardless of the form of action, whether in contract or tort, including negligence. Any action
against National Instruments must be brought within one year after the cause of action accrues. National Instruments
shall not be liable for any delay in performance due to causes beyond its reasonable control. The warranty provided
herein does not cover damages, defects, malfunctions, or service failures caused by owner’s failure to follow the
National Instruments installation, operation, or maintenance instructions; owner’s modification of the product;
owner’s abuse, misuse, or negligent acts; and power failure or surges, fire, flood, accident, actions of third parties, or
other events outside reasonable control.
Copyright
Under the copyright laws, this publication may not be reproduced or transmitted in any form, electronic or
mechanical, including photocopying, recording, storing in an information retrieval system, or translating, in whole or
in part, without the prior written consent of National Instruments Corporation.
Trademarks
LabVIEW , NI-DAQ , ComponentWorks , DAQ-STC , MANTIS , MITE , NI-PGIA , NI-VISA , NI-VXI
SCXI , and VirtualBench are trademarks of National Instruments Corporation.
,
Product and company names listed are trademarks or trade names of their respective companies.
WARNING REGARDING MEDICAL AND CLINICAL USE OF NATIONAL INSTRUMENTS PRODUCTS
National Instruments products are not designed with components and testing intended to ensure a level of reliability
suitable for use in treatment and diagnosis of humans. Applications of National Instruments products involving
medical or clinical treatment can create a potential for accidental injury caused by product failure, or by errors on the
part of the user or application designer. Any use or application of National Instruments products for or involving
medical or clinical treatment must be performed by properly trained and qualified medical personnel, and all
traditional medical safeguards, equipment, and procedures that are appropriate in the particular situation to prevent
serious injury or death should always continue to be used when National Instruments products are being used.
National Instruments products are NOT intended to be a substitute for any form of established process, procedure, or
equipment used to monitor or safeguard human health and safety in medical or clinical treatment.
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Table
of
Contents
About This Manual
Organization of This Manual ........................................................................................xi
National Instruments Documentation ...........................................................................xiii
Related Documentation .................................................................................................xiv
Customer Communication ............................................................................................xiv
Chapter 1
What You Need to Get Started ......................................................................................1-2
Software Programming Choices ...................................................................................1-2
National Instruments Application Software ...................................................1-2
NI-DAQ Driver Software ...............................................................................1-3
VXIplug&play Instrument Drivers .................................................................1-4
Optional Equipment ......................................................................................................1-5
Custom Cabling .............................................................................................................1-6
Unpacking .....................................................................................................................1-6
VXIbus Logical Address ................................................................................2-1
SIMM Size ......................................................................................................2-5
Load USER/FACTORY Configuration ..........................................................2-7
Protect/Change Factory Configuration ...........................................................2-8
Hardware Installation ....................................................................................................2-8
Software Installation .....................................................................................................2-9
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Table of Contents
Analog Input ................................................................................................................. 3-3
Input Polarity and Input Range ...................................................................... 3-4
Considerations for Selecting Input Ranges ...................................... 3-6
Analog Output .............................................................................................................. 3-10
Analog Output Reference Selection ............................................................... 3-10
Analog Output Polarity Selection .................................................................. 3-10
Analog Output Reglitch Selection ................................................................. 3-11
Analog Trigger ............................................................................................................. 3-11
Digital I/O ..................................................................................................................... 3-14
Timing Signal Routing ................................................................................................. 3-15
Programmable Function Inputs ...................................................................... 3-16
Module and Timebase .................................................................................... 3-16
Chapter 4
I/O Connector ............................................................................................................... 4-1
I/O Connector Signal Descriptions ................................................................ 4-3
Analog Input Signal Connections ................................................................................. 4-9
Types of Signal Sources ............................................................................................... 4-11
Floating Signal Sources .................................................................................. 4-11
Differential Connection Considerations (DIFF Input Configuration) ........... 4-14
Differential Connections for Ground-Referenced
Signal Sources ................................................................................ 4-15
Differential Connections for Nonreferenced or Floating
Signal Sources ................................................................................ 4-16
(RSE Configuration) ...................................................................... 4-19
Single-Ended Connections for Grounded Signal Sources
(NRSE Configuration) ................................................................... 4-19
Common-Mode Signal Rejection Considerations .......................................... 4-20
Analog Output Signal Connections .............................................................................. 4-20
Digital I/O Signal Connections .................................................................................... 4-22
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EXTSTROBE* Signal ......................................................................4-26
TRIG1 Signal ...................................................................................4-27
TRIG2 Signal ...................................................................................4-28
STARTSCAN Signal .......................................................................4-30
AIGATE Signal ................................................................................4-33
SISOURCE Signal ...........................................................................4-34
WFTRIG Signal ...............................................................................4-36
UPDATE* Signal .............................................................................4-36
UISOURCE Signal ...........................................................................4-37
General-Purpose Timing Signal Connections ................................................4-38
GPCTR1_SOURCE Signal ..............................................................4-41
GPCTR1_GATE Signal ...................................................................4-41
GPCTR1_UP_DOWN Signal ..........................................................4-43
FREQ_OUT Signal ..........................................................................4-44
Field Wiring Considerations .........................................................................................4-45
Calibration
Loading Calibration Constants ......................................................................................5-1
Self-Calibration .............................................................................................................5-2
External Calibration ......................................................................................................5-2
Other Considerations .....................................................................................................5-3
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Appendix A
VXI-MIO-64E-1 ........................................................................................................... A-1
VXI-MIO-64XE-10 ...................................................................................................... A-10
Appendix B
Optional Cable Connector Descriptions
Appendix C
Customer Communication
Index
Instrument Driver, and Your VXI-DAQ Hardware .............................. 1-5
Figure 2-1. VXI-MIO-64E-1 Parts Locator Diagram ................................................ 2-3
Figure 2-4. SIMM Size Configuration ....................................................................... 2-6
Figure 2-5. Load User/Factory Configuration ........................................................... 2-8
Figure 2-6. Protect/Change Factory Configuration .................................................... 2-8
Figure 3-1. VXI-MIO Series Block Diagram ............................................................ 3-2
Figure 3-2. Dither ....................................................................................................... 3-8
Figure 3-3. Analog Trigger Block Diagram ............................................................... 3-12
Figure 3-5. Above-High-Level Analog Triggering Mode ......................................... 3-13
Figure 3-6. Inside-Region Analog Triggering Mode ................................................. 3-13
Figure 3-7. High-Hysteresis Analog Triggering Mode .............................................. 3-13
Figure 3-8. Low-Hysteresis Analog Triggering Mode .............................................. 3-14
Figure 3-9. CONVERT* Signal Routing ................................................................... 3-15
Figure 3-10. VXIbus Trigger Utilization ..................................................................... 3-17
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Figure 4-1. I/O Connector Pin Assignment for the VXI-MIO-64E-1 and
VXI-MIO-64XE-10 ................................................................................4-2
Figure 4-2. VXI-MIO Series PGIA ............................................................................4-10
Figure 4-3. Summary of Analog Input Connections ..................................................4-13
Signals.....................................................................................................4-19
Figure 4-7. Single-Ended Input Connections for Ground-Referenced Signal ............4-20
Figure 4-8. Analog Output Connections .....................................................................4-21
Figure 4-9. Digital I/O Connections ...........................................................................4-22
Figure 4-10. Timing I/O Connections ..........................................................................4-24
Figure 4-11. Typical Posttriggered Acquisition ...........................................................4-25
Figure 4-12. Typical Pretriggered Acquisition .............................................................4-26
Figure 4-14. EXTSTROBE* Signal Timing ................................................................4-27
Figure 4-18. TRIG2 Output Signal Timing ..................................................................4-29
Figure 4-19. STARTSCAN Input Signal Timing .........................................................4-30
Figure 4-20. STARTSCAN Output Signal Timing ......................................................4-31
Figure 4-21. CONVERT* Input Signal Timing ...........................................................4-32
Figure 4-24. WFTRIG Input Signal Timing .................................................................4-35
Figure 4-25. WFTRIG Output Signal Timing ..............................................................4-35
Figure 4-26. UPDATE* Input Signal Timing ..............................................................4-37
Figure 4-28. UISOURCE Signal Timing ......................................................................4-38
Figure 4-30. GPCTR0_GATE Signal Timing in Edge-Detection Mode .....................4-40
Figure 4-31. GPCTR0_OUT Signal Timing ................................................................4-40
Figure 4-33. GPCTR1_GATE Signal Timing in Edge-Detection Mode .....................4-42
Figure 4-34. GPCTR1_OUT Signal Timing ................................................................4-43
Figure 4-35. GPCTR Timing Summary .......................................................................4-43
Figure B-1. 68-Pin MIO Connector Pin Assignments ................................................B-2
Figure B-2. 68-Pin Extended Analog Input Connector Pin Assignments ...................B-3
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Tables
Table 3-1. Available Input Configurations for the VXI-MIO Series ....................... 3-3
Table 3-2. Actual Range and Measurement Precision .............................................. 3-4
Table 3-3. Actual Range and Measurement Precision, VXI-MIO-64XE-10 ........... 3-6
Table 4-1. VXI-MIO-64E-1 I/O Signal Summary .................................................... 4-6
Table 4-2. VXI-MIO-64XE-10 I/O Signal Summary ............................................... 4-8
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About
This
Manual
This manual describes the electrical and mechanical aspects of each
module in the VXI-MIO Series product line and contains information
concerning their installation, operation, and programming. Unless
otherwise noted, text applies to all modules in the VXI-MIO Series.
The VXI-MIO Series includes the following modules:
•
•
VXI-MIO-64E-1
VXI-MIO-64XE-10
The VXI-MIO Series modules are high-performance multifunction
analog, digital, and timing I/O modules for VXIbus.
Organization of This Manual
The VXI-MIO Series User Manual is organized as follows:
•
Chapter 1, Introduction, describes the VXI-MIO Series modules,
lists what you need to get started, describes the optional software
and optional equipment, and explains how to unpack your
VXI-MIO Series module.
•
•
•
Chapter 2, Configuration and Installation, explains how to
configure and install your VXI-MIO Series module.
Chapter 3, Hardware Overview, presents an overview of the
hardware functions on your VXI-MIO Series module.
Chapter 4, Signal Connections, describes how to make input and
output signal connections to your VXI-MIO Series module via the
module I/O connector.
•
•
•
Chapter 5, Calibration, discusses the calibration procedures for
your VXI-MIO Series module.
Appendix A, Specifications, lists the specifications for each
module in the VXI-MIO Series.
Appendix B, Optional Cable Connector Descriptions, describes the
connectors on the optional cables for the VXI-MIO Series modules.
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About This Manual
•
•
•
•
Appendix C, Common Questions, contains a list of commonly asked
questions and their answers relating to usage and special features
of your VXI-MIO Series module.
Appendix D, Customer Communication, contains forms you can use
to request help from National Instruments or to comment on our
products.
The Glossary contains an alphabetical list and description of terms
used in this manual, including acronyms, abbreviations, metric
prefixes, mnemonics, and symbols.
The Index alphabetically lists topics covered in this manual,
including the page where you can find the topic.
Conventions Used in This Manual
The following conventions are used in this manual.
♦
The ♦ indicates that the text following it applies only to specific
VXI-MIO Series modules.
< >
Angle brackets containing numbers separated by an ellipsis represent a
range of values associated with a bit, port, or signal name (for example,
ACH<0..7> stands for ACH0 through ACH7).
bold
Bold text denotes parameters.
bold italic
italic
Bold italic text denotes a note, caution, or warning.
Italic text denotes emphasis on a specific module in the
VXI-MIO Series or on other important information, a cross reference,
or an introduction to a key concept.
NI-DAQ
SCXI
NI-DAQ refers to the NI-DAQ software for PC compatibles unless
otherwise noted.
SCXI stands for Signal Conditioning eXtensions for Instrumentation
and is a National Instruments product line designed to perform
front-end signal conditioning for National Instruments plug-in DAQ
boards.
The Glossary lists abbreviations, acronyms, metric prefixes,
mnemonics, symbols, and terms.
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About This Manual
National Instruments Documentation
The VXI-MIO Series User Manual is one piece of the documentation set
for your VXI-DAQ system. You could have any of several types of
manuals depending on the hardware and software in your system. Use
the manuals you have as follows:
•
•
•
Getting Started with SCXI—If you are using SCXI, this is the first
manual you should read. It gives an overview of the SCXI system
and contains the most commonly needed information for the
modules, chassis, and software.
Your SCXI hardware user manuals—If you are using SCXI, read
these manuals next for detailed information about signal
connections and module configuration. They also explain in greater
detail how the module works and contain application hints.
Your VXI-DAQ hardware user manuals—These manuals have
detailed information about the VXI-DAQ hardware that plugs into
or is connected to your system. Use these manuals for hardware
installation and configuration instructions, specification
information about your VXI-DAQ hardware, and application hints.
•
Software documentation—You may have both application software
and driver software documentation. National Instruments
application software includes ComponentWorks, LabVIEW,
LabWindows /CVI, Measure, and VirtualBench. National
Instruments driver software includes NI-DAQ and VXIplug&play
instrument drivers. After you set up your hardware system, use
either your application or driver software documentation to help
you write your application. If you have a large and complicated
system, it is worthwhile to look through the software
documentation before you configure your hardware.
•
•
Accessory installation guides or manuals—If you are using
accessory products, read the terminal block and cable assembly
installation guides. They explain how to physically connect the
relevant pieces of the system. Consult these guides when you are
making your connections.
SCXI chassis manuals—If you are using SCXI, read these manuals
for maintenance information on the chassis and installation
instructions.
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About This Manual
Related Documentation
The following National Instruments document contains information
you may find helpful:
•
Application Note 025, Field Wiring and Noise Considerations for
Analog Signals
Customer Communication
National Instruments wants to receive your comments on our products
and manuals. We are interested in the applications you develop with our
products, and we want to help if you have problems with them. To make
it easy for you to contact us, this manual contains comment and
configuration forms for you to complete. These forms are in
Appendix D, Customer Communication, at the end of this manual.
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Chapter
1
Introduction
This chapter describes the VXI-MIO Series modules, lists what you
need to get started, describes the optional software and optional
equipment, and explains how to unpack your VXI-MIO Series module.
About the VXI-MIO Series
Thank you for buying a National Instruments VXI-MIO Series module.
The VXI-MIO Series modules are completely VXIplug&play-
compatible multifunction analog, digital, and timing I/O modules for
VXIbus. This family of modules features 12-bit and 16-bit ADCs with
64 analog inputs, 12-bit and 16-bit DACs with voltage outputs, eight
lines of TTL-compatible digital I/O, and two 24-bit counter/timers for
timing I/O.
The VXI-MIO Series modules use the National Instruments DAQ-STC
system timing controller for timer-related functions. The DAQ-STC
consists of three timing groups that control analog input, analog output,
and general-purpose counter/timer functions. These groups include a
total of seven 24-bit and three 16-bit counters and a maximum timing
resolution of 50 ns.
A common problem with other VXI modules is that you cannot easily
synchronize several measurement functions to a common trigger or
timing event. The VXI-MIO Series modules solve this problem by
using VXIbus triggers to synchronize measurements on several
VXI-MIO Series modules.
You can interface the VXI-MIO Series modules to an SCXI signal
conditioning and multiplexing system to acquire over 3,000 analog
signals from thermocouples, RTDs, strain gauges, voltage sources, and
current sources. You can also acquire or generate digital signals for
communication and control.
Detailed specifications of the VXI-MIO Series modules are in
Appendix A, Specifications.
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Chapter 1 Introduction
What You Need to Get Started
To set up and use your VXI-MIO Series module, you will need the
following:
❑ One of the following modules:
VXI-MIO-64E-1
VXI-MIO-64XE-10
❑ VXI-MIO Series User Manual
❑ One or more of the following software packages and documentation:
ComponentWorks
LabVIEW for Windows
LabWindows/CVI
Measure
NI-DAQ for PC Compatibles
VirtualBench
VXIplug&play instrument driver
❑ Your VXIbus system
Software Programming Choices
There are several options to choose from when programming your
National Instruments VXI-DAQ hardware. You can use LabVIEW,
LabWindows/CVI, Measure, ComponentWorks, VirtualBench, or other
application development environments with either NI-DAQ or the
VXIplug&play instrument driver. Both NI-DAQ and the VXIplug&play
instrument drivers access the VXI-DAQ hardware through the VISA
driver software.
National Instruments Application Software
ComponentWorks contains tools for data acquisition and instrument
control built on NI-DAQ driver software. ComponentWorks provides a
higher-level programming interface for building virtual instruments
through standard OLE controls and DLLs. With ComponentWorks, you
can use all of the configuration tools, resource management utilities,
and interactive control utilities included with NI-DAQ.
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Chapter 1 Introduction
LabVIEW features interactive graphics, a state-of-the-art user
interface, and a powerful graphical programming language. The
LabVIEW Data Acquisition VI Library, a series of VIs for using
LabVIEW with National Instruments DAQ hardware, is included with
LabVIEW. The LabVIEW Data Acquisition VI Library is functionally
equivalent to the NI-DAQ software.
LabWindows/CVI features interactive graphics, a state-of-the-art user
interface, and uses the ANSI standard C programming language. The
LabWindows/CVI Data Acquisition Library, a series of functions for
using LabWindows/CVI with National Instruments DAQ hardware, is
included with the NI-DAQ software kit. The LabWindows/CVI Data
Acquisition Library is functionally equivalent to the NI-DAQ software.
VirtualBench features VIs that combine DAQ products, software, and
your computer to create a standalone instrument with the added benefit
of the processing, display, and storage capabilities of your computer.
VirtualBench instruments load and save waveform data to disk in the
same forms that can be used in popular spreadsheet programs and word
processors. VirtualBench features report generation and printing
capabilities.
Using ComponentWorks, LabVIEW, LabWindows/CVI, or
VirtualBench software will greatly reduce the development time for
your data acquisition and control application.
NI-DAQ Driver Software
The NI-DAQ driver software is included at no charge with all National
Instruments DAQ hardware. NI-DAQ is not packaged with signal
conditioning or accessory products. NI-DAQ has an extensive library of
functions that you can call from your application programming
environment. These functions include routines for analog input (A/D
conversion), buffered data acquisition (high-speed A/D conversion),
analog output (D/A conversion), waveform generation (timed D/A
conversion), digital I/O, counter/timer operations, SCXI, triggering,
calibration, messaging, and acquiring data to extended memory.
NI-DAQ has both high-level DAQ I/O functions for maximum ease of
use and low-level DAQ I/O functions for maximum flexibility and
performance. Examples of high-level functions are streaming data to
disk or acquiring a certain number of data points. An example of a
low-level function is writing directly to registers on the DAQ device.
NI-DAQ does not sacrifice the performance of National Instruments
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Chapter 1 Introduction
DAQ devices because it lets multiple devices operate at their peak
performance.
NI-DAQ also internally addresses many of the complex issues between
the computer and the DAQ hardware such as programming interrupts
and DMA controllers. NI-DAQ maintains a consistent software
interface between its different versions so that you can change
platforms with minimal modifications to your code.
VXIplug&play Instrument Drivers
National Instruments distributes VXIplug&play instrument drivers free
of charge. VXIplug&play instrument drivers are one level above the
NI-DAQ device driver and contain high-level software functions whose
architecture is specified by the VXIplug&play Systems Alliance. The
VXIplug&play standards increase interoperability with other vendors,
and ensure that drivers are designed and presented in a consistent
fashion that facilitates ease of use. Refer to Figure 1-1 to see the
relationship between your software components.
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Chapter 1 Introduction
LabVIEW or
LabWindows/CVI
Other Application
Development Environments
VXIplug&play
Instrument Driver
NI-DAQ Driver Software
VISA
VXI-DAQ Hardware
Figure 1-1. The Relationship between the Programming Environment, Your
Instrument Driver, and Your VXI-DAQ Hardware
Optional Equipment
National Instruments offers a variety of products to use with your
VXI-MIO Series module, including cables, connector blocks, and other
accessories, as follows:
•
•
•
Cables and cable assemblies, shielded and ribbon
Connector blocks
SCXI modules and accessories for isolating, amplifying, exciting,
and multiplexing signals for relays and analog output. With SCXI
you can condition and acquire up to 3072 channels.
•
Low channel count signal conditioning modules, boards, and
accessories, including conditioning for strain gauges and RTDs,
simultaneous sample and hold, and relays
For more specific information about these products, refer to your
National Instruments catalogue or call the office nearest you.
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Chapter 1 Introduction
Custom Cabling
Mating connectors and a backshell kit for making custom 96-pin cables
for your VXI-MIO Series module are available from National
Instruments.
If you want to develop your own cable, however, the following
guidelines may be useful:
•
For the analog input signals, shielded twisted-pair wires for each
signal yields the best results, assuming that you use differential
inputs. Tie the shield for each signal pair to the ground reference at
the source.
•
•
You should route the analog lines separately from the digital lines.
When using a cable shield, use separate shields for the analog and
digital halves of the cable. Failure to do so results in noise coupling
into the analog signals from transient digital signals.
Unpacking
Your VXI-MIO Series module is shipped in an antistatic package to
prevent electrostatic damage to the module. Electrostatic discharge can
damage several components on the module. To avoid such damage in
handling the module, take the following precautions:
•
•
•
Ground yourself via a grounding strap or by holding a grounded
object.
Touch the antistatic package to a metal part of your VXIbus chassis
before removing the module from the package.
Remove the module from the package and inspect the module for
loose components or any other sign of damage. Notify National
Instruments if the module appears damaged in any way. Do not
install a damaged module into your VXIbus chassis.
•
Never touch the exposed pins of connectors.
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Chapter
Configuration and
Installation
2
This chapter explains how to configure and install your
VXI-MIO Series module.
Module Configuration
The VXI-MIO Series modules are software-configurable, except for the
VXIbus logical address. You must perform two types of configuration
on the VXI-MIO Series modules—bus-related configuration and data
acquisition-related configuration. Bus-related configuration includes
setting the VXIbus logical address, VXIbus address space (A24 versus
A32), VXIbus interrupt levels, and amount of VXIbus address space
required. Data acquisition-related configuration, explained in
Chapter 3, Hardware Overview, includes such settings as analog input
polarity and range, analog output reference source, and other settings.
VXIbus Logical Address
Each module in a VXIbus system is assigned a unique number between
0 and 254. This 8-bit number, called the logical address, defines the
base address for the VXIbus configuration registers located on the
module. With unique logical addresses, each VXIbus module in the
system is assigned 64 bytes of configuration space in the upper 16 KB
of the A16 address space.
Logical address 0 is reserved for the Resource Manager in the VXIbus
system. Because the VXI-MIO Series modules cannot act as a Resource
Manager, do not configure the VXI-MIO Series modules with a logical
address of 0. The factory-default logical address for the
VXI-MIO-64E-1 is 3 and for the VXI-MIO-64XE-10 is 2.
Some VXIbus modules have dynamically configurable logical
addresses. These modules have an initial logical address of hex FF or
decimal 255, which indicates that they can be dynamically configured.
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Chapter 2 Configuration and Installation
Your VXI-MIO Series module does not support dynamic configuration
of its logical address.
Ensure that no other statically configurable VXIbus modules have the
same logical address as the VXI-MIO Series module. If they do, change
the logical address setting of either the VXI-MIO Series module or the
other module so that every module in the system has a different
associated logical address.
To change the logical address of the VXI-MIO Series modules, modify
the setting of the 8-bit DIP switch labeled LOGICAL ADDRESS
SWITCH (U3 for the VXI-MIO-64E-1 and U73 for the
VXI-MIO-64XE-10). The down position of the DIP switch corresponds
to a logic value of 0 and the up position corresponds to a logic value
of 1.
See Figures 2-1 and 2-2 for the VXI-MIO Series parts locator diagrams.
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4
3
2
5
1
1
6
7
8
9
11
P3
Serial Number
S1
10
1
2
3
DRAM
4
5
6
7
8
9
S2
S3
10 P1
11 P2
Product Name
Assembly Number
Logical Address Switch
Figure 2-1. VXI-MIO-64E-1 Parts Locator Diagram
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4
3
2
1
1
5
6
7
8
11
10
9
1
2
3
DRAM
Product Name
Assembly Number
4
5
6
P3
S1
S2
7
8
9
S3
10 P1
11 P2
Logical Address Switch (U73)
Serial Number
Figure 2-2. VXI-MIO-64XE-10 Block Diagram
Figure 2-3 shows the VXI-MIO-64XE-10 switch settings for logical
address 2 and 192.
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Logical Address
Switch
Push up for logic 1
Push down for logic 0
1
2 3 4 5 6 7
8
LSB
MSB
P1 Connector
U73
VXI-MIO-64XE-10 Module
a. Switch Set to Logical Address 2 (Default)
Logical Address
Switch
Push up for logic 1
Push down for logic 0
1
2 3 4 5 6 7
8
LSB
MSB
P1 Connector
U73
b. Switch Set to Logical Address 192
VXI-MIO-64XE-10 Module
Figure 2-3. VXI-MIO-64XE-10 Logical Address Selection
SIMM Size
Each VXI-MIO module can accommodate up to two 1.35 in. DRAM
SIMMs. Table 2-1 lists the SIMMS you can use. You can use 32-bit or
36-bit SIMMS since DRAM parity is not required. Because the
VXI-MIO module supports only one organization at a time, all SIMMs
installed must be of the same type. Use bank 0 first when installing the
SIMMs, so that you can install up to 64 MB. The VXI-MIO module
supports DRAM speeds of 80 ns or faster.
Use switch S3 to select the size of each SIMM. The SIMM sockets are
accessible only by removing the component right side cover, but S3 is
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accessible with the cover on. To access the SIMM sockets, perform the
following steps:
1. Remove the four screws on the top, the four screws on the bottom,
and the three screws on the right-side cover of the metal enclosure.
2. If the SIMMs are 4 MB x 32 bit or larger, set S3 as shown in
Figure 2-4a.
3. For SIMMs smaller than 4 MB x 32 bit, set S3 as shown in
Figure 2-4b.
SIMM Size
SIMM Size
(Factory Default)
(Factory Default)
S3
S3
a. 4 MB X 32 bit or larger
b. Smaller than 4 MB X 32 bit
Figure 2-4. SIMM Size Configuration
Refer to Table 2-1 to properly adjust the switch (ON or OFF) for all
supported DRAM configurations. Many of the DRAM options are
available from National Instruments.
Table 2-1. VXI-MIO Series DRAM Configuration
Bank 0
Bank 1
Total
DRAM
National
Instruments Option
Switch Setting
of S3
—
—
—
0
—
—
—
256 KB x 32 bit or
256 KB x 36 bit
1 MB
ON
256 KB x 32 bit or
256 KB x 36 bit
256 KB x 32 bit or
256 KB x 36 bit
2 MB
2 MB
4 MB
—
—
—
ON
ON
ON
512 KB x 32 bit or
512 KB x 36 bit
—
512 KB x 32 bit or
512 KB x 36 bit
512 KB x 32 bit or
512 KB x 36 bit
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Table 2-1. VXI-MIO Series DRAM Configuration (Continued)
Bank 0
Bank 1
Total
DRAM
National
Instruments Option
Switch Setting
of S3
1 MB x 32 bit or
1 MB x 36 bit
—
4 MB
8 MB
Yes
—
ON
1 MB x 32 bit or
1 MB x 36 bit
1 MB x 32 bit or
1 MB x 36 bit
ON
2 MB x 32 bit or
2 MB x 36 bit
—
8 MB
Yes
—
ON
2 MB x 32 bit or
2 MB x 36 bit
2 MB x 32 bit or
2 MB x 36 bit
16 MB
16 MB
32 MB
32 MB
64 MB
ON
4 MB x 32 bit or
4 MB x 36 bit
—
Yes
—
OFF
OFF
OFF
OFF
4 MB x 32 bit or
4 MB x 36 bit
4 MB x 32 bit or
4 MB x 36 bit
8 MB x 32 bit or
8 MB x 36 bit
—
Yes
Yes
8 MB x 32 bit or
8 MB x 36 bit
8 MB x 32 bit or
8 MB x 36 bit
Load USER/FACTORY Configuration
The VXI-MIO module has an onboard EEPROM, which stores default
register values that are loaded at power-on. The EEPROM is divided
into two halves—a factory-configuration half, and a user-configuration
half. Both halves were factory configured with the same configuration
values so you can modify the user-configurable half, while the factory-
configured half stores a back-up of the factory settings.
Use switch S2 to control the operation of the EEPROM. The switch
causes the VXI-MIO module to boot off the factory-configured half
instead of the user-modified settings. This is useful in the event that the
user-configured half of the EEPROM becomes corrupted in such a way
that the VXI-MIO module boots to an unusable state. Refer to
Figure 2-5 for configuration settings.
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Load User
Configuration
Load Factory
Configuration
S2
S2
Figure 2-5. Load User/Factory Configuration
Protect/Change Factory Configuration
Use switch S1 to change the factory-default configuration settings by
permitting writes to the factory settings section of the EEPROM. This
switch serves as a safety measure and should not be needed under
normal circumstances. When this switch is off (its default setting) the
factory configuration of the EEPROM is protected, so any writes to the
factory area will be ignored. Refer to Figure 2-6 for configuration
settings.
Protect Factory
Configuration
Change Factory
Configuration
S1
S1
Figure 2-6. Protect/Change Factory Configuration
Hardware Installation
This section contains general installation instructions for the VXI-MIO
Series modules. Consult your VXIbus mainframe user manual or
technical reference manual for specific instructions and warnings.
1. Plug in your mainframe before installing your VXI module. The
power cord grounds the mainframe and protects it from electrical
damage while you install the module. Do not turn on the
mainframe.
Warning: To protect yourself and your mainframe from electrical hazards, DO NOT
turn the mainframe on until you are finished installing your VXI-MIO
Series module.
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2. Remove or open any doors or covers blocking access to the
mainframe slots.
3. If you are installing your VXI-DAQ module into a D-size
mainframe, first install an appropriate support for C-size modules
in D-size mainframes.
4. Insert the VXI-DAQ module in the slot you have selected:
a. Align the top and bottom of the module with the card-edge
guides inside the mainframe.
b. Slowly push the VXI-DAQ module straight into the slot until
its plug connectors are resting on the backplane receptacle
connectors.
c. Using evenly distributed pressure, slowly press the VXI-DAQ
module straight in until it seats in the expansion slot.
d. Make sure the front panel of the VXI-DAQ module is even
with the front panel of the mainframe.
5. Tighten the retaining screws on the top and bottom edges of the
front panel.
6. Replace or close any doors or covers to the mainframe.
Software Installation
Regardless of your programming methodology, proper operation of
your VXI-MIO module depends on the correct installation of VISA on
your VXIbus controller.
If VISA is not installed, you must get this information from your
VXIbus controller manufacturer. If you have a National Instruments
VXIbus controller, contact our sales department for information on
obtaining the NI-VISA software at no charge.
If you are using NI-DAQ, refer to your release notes. Find the
installation section for your operating system and follow the
instructions given there.
If you are using LabVIEW, refer to your LabVIEW release notes to
install your application software. After you have installed LabVIEW,
refer to the NI-DAQ release notes and follow the instructions given
there for your operating system and LabVIEW.
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If you are using LabWindows/CVI, refer to your LabWindows/CVI
release notes to install your application software. After you have
installed LabWindows/CVI, refer to the NI-DAQ release notes and
follow the instructions given there for your operating system and
LabWindows/CVI.
If you are using ComponentWorks, Measure, or VirtualBench
application software, refer to your documentation for installation
instructions.
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Hardware Overview
This chapter presents an overview of the hardware functions on your
VXI-MIO Series module.
Figure 3-1 shows the block diagram for the VXI-MIO Series modules.
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Analog Input
The analog input section of each VXI-MIO Series module is software
configurable. You can select different analog input configurations
through application software designed to control the VXI-MIO Series
modules. The following sections describe in detail each of the analog
input categories.
Input Mode
The VXI-MIO Series modules have three different input modes—
nonreferenced single-ended (NRSE) input, referenced single-ended
(RSE) input, and differential (DIFF) input. The single-ended input
configurations use up to 64 channels. The DIFF input configuration
uses up to 32 channels. Input modes are programmed on a per channel
basis for multimode scanning. For example, you can configure the
circuitry to scan 48 channels—16 differentially-configured channels
and 32 single-ended channels. Table 3-1 describes the three input
configurations.
Table 3-1. Available Input Configurations for the VXI-MIO Series
Configuration
Description
DIFF
A channel configured in DIFF mode uses two analog
input channel lines. One line connects to the positive
input of the module programmable gain
instrumentation amplifier (PGIA), and the other
connects to the negative input of the PGIA.
RSE
A channel configured in RSE mode uses one analog
input channel line, which connects to the positive
input of the PGIA. The negative input of the PGIA is
internally tied to analog input ground (AIGND).
NRSE
A channel configured in NRSE mode uses one
analog input channel line, which connects to the
positive input of the PGIA. The negative input of the
PGIA connects to the analog input sense (AISENSE)
input.
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For more information about the three types of input configuration, refer
to the Analog Input Signal Connections section in Chapter 4, Signal
Connections, which contains diagrams showing the signal paths for the
three configurations.
Input Polarity and Input Range
♦
VXI-MIO-64E-1
This module has two input polarities—unipolar and bipolar. The
VXI-MIO-64E-1 has a unipolar input range of 10 V (0 to 10 V) and
a bipolar input range of 10 V (±5 V). You can program polarity and
range settings on a per channel basis so that you can configure each
input channel uniquely.
The software-programmable gain on this module increases its
overall flexibility by matching the input signal ranges to those that
the ADC can accommodate. The VXI-MIO-64E-1 has gains of 0.5,
1, 2, 5, 10, 20, 50, and 100 and is suited for a wide variety of signal
levels. With the proper gain setting, you can use the full resolution
of the ADC to measure the input signal. Table 3-2 shows the
overall input range and precision according to the configuration
and gain used.
Table 3-2. Actual Range and Measurement Precision
1
Range
Gain
Actual Input Range
Precision
Configuration
0 to +10 V
1.0
2.0
0 to +10 V
0 to +5 V
2.44 mV
1.22 mV
5.0
0 to +2 V
0 to +1 V
0 to +500 mV
0 to +200 mV
0 to +100 mV
488.28 µV
244.14 µV
122.07 µV
48.83 µV
24.41 µV
10.0
20.0
50.0
100.0
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Table 3-2. Actual Range and Measurement Precision (Continued)
1
Range
Gain
Actual Input Range
Precision
Configuration
-5 to +5 V
0.5
1.0
-10 to +10 V
-5 to +5 V
4.88 mV
2.44 mV
2.0
5.0
10.0
20.0
50.0
100.0
-2.5 to +2.5 V
-1 to +1 V
-500 to +500 mV
-250 to +250 mV
-100 to +100 mV
-50 to +50 mV
1.22 mV
488.28 µV
244.14 µV
122.07 µV
48.83 µV
24.41 µV
1
The value of 1 LSB of the 12-bit ADC; that is, the voltage
increment corresponding to a change of one count in the ADC
12-bit count.
Note: See Appendix A, Specifications, for absolute maximum
ratings.
♦
VXI-MIO-64XE-10
This module has two input polarities—unipolar and bipolar. The
VXI-MIO-64XE-10 has a unipolar input range of 10 V (0 to 10 V)
and a bipolar input range of 20 V (±10 V). You can program
polarity and range settings on a per channel basis so that you can
configure each input channel uniquely.
Note:
You can calibrate your VXI-MIO-64XE-10 analog input circuitry for
either a unipolar or bipolar polarity. If you mix unipolar and bipolar
channels in your scan list and you are using NI-DAQ, then NI-DAQ will
load the calibration constants appropriate to the polarity for which analog
input channel 0 is configured.
The software-programmable gain on this module increases its
overall flexibility by matching the input signal ranges to those that
the ADC can accommodate. The VXI-MIO-64XE-10 has gains of
1, 2, 5, 10, 20, 50, and 100. These gains are suited for a wide variety
of signal levels. With the proper gain setting, you can use the full
resolution of the ADC to measure the input signal. Table 3-3 shows
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the overall input range and precision according to the configuration
and gain used.
Table 3-3. Actual Range and Measurement Precision, VXI-MIO-64XE-10
1
Range
Gain
Actual Input Range
Precision
Configuration
0 to +10 V
1.0
2.0
5.0
10.0
20.0
50.0
100.0
0 to +10 V
0 to +5 V
0 to +2 V
152.59 µV
76.29 µV
30.52 µV
15.26 µV
7.63µV
0 to +1 V
0 to +500 mV
0 to +200 mV
0 to 100 mV
3.05 µV
1.53 µV
-10 to +10 V
1.0
2.0
5.0
10.0
20.0
50.0
100.0
-10 to +10 V
-5 to +5 V
-2 to +2 V
305.18 µV
152.59 µV
61.04 µV
30.52 µV
15.26 µV
6.10 µV
-1 to +1 V
-500 to +500 mV
-200 to +200 mV
-100 to +100 mV
3.05 µV
1
The value of 1 LSB of the 12-bit ADC; that is, the voltage
increment corresponding to a change of one count in the ADC
12-bit count.
Note:See Appendix A, Specifications, for absolute maximum
ratings.
Considerations for Selecting Input Ranges
Which input polarity and range you select depends on the expected
range of the incoming signal. A large input range can accommodate a
large signal variation but reduces the voltage resolution. Choosing a
smaller input range improves the voltage resolution but may result in
the input signal going out of range. For best results, you should match
the input range as closely as possible to the expected range of the input
signal. For example, if you are certain the input signal will not be
negative (below 0 V), unipolar input polarity is best. However, if the
signal is negative or equal to zero, using unipolar input polarity will
yield inaccurate readings.
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Dither
When you enable dither, you add approximately 0.5 LSB rms of white
Gaussian noise to the signal to be converted by the ADC. This addition
is useful for applications involving averaging to increase the resolution
of your VXI-MIO Series module, as in calibration or spectral analysis.
In such applications, noise modulation is decreased and differential
linearity is improved by the addition of the dither. When taking DC
measurements, such as when checking the module calibration, you
should enable dither and average about 1,000 points to take a single
reading. This process removes the effects of quantization and reduces
measurement noise, resulting in improved resolution. For high-speed
applications not involving averaging or spectral analysis, you may want
to disable the dither to reduce noise. You enable and disable the dither
circuitry through software.
Figure 3-2 illustrates the effect of dither on signal acquisition.
Figure 3-2a shows a small (±4 LSB) sine wave acquired with dither off.
The quantization of the ADC is clearly visible. Figure 3-2b shows what
happens when 50 such acquisitions are averaged together; quantization
is still plainly visible. In Figure 3-2c, the sine wave is acquired with
dither on. There is a considerable amount of noise visible. But
averaging about 50 such acquisitions, as shown in Figure 3-2d,
eliminates both the added noise and the effects of quantization. Dither
has the effect of forcing quantization noise to become a zero-mean
random variable rather than a deterministic function of the input signal.
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LSBs
6.0
LSBs
6.0
4.0
2.0
4.0
2.0
0.0
0.0
-2.0
-4.0
-2.0
-4.0
-6.0
-6.0
0
100
200
300
400
500
0
100
200
300
400
500
a. Dither disabled; no averaging
b. Dither disabled; average of 50 acquisitions
LSBs
6.0
LSBs
6.0
4.0
4.0
2.0
2.0
0.0
0.0
-2.0
-4.0
-2.0
-4.0
-6.0
-6.0
0
100
200
300
400
500
0
100
200
300
400
500
c. Dither enabled; no averaging
d. Dither enabled; average of 50 acquisitions
Figure 3-2. Dither
You cannot disable dither on the VXI-MIO-64XE-10. This is because
the ADC resolution is so fine that the ADC and the PGIA inherently
produce almost 0.5 LSB rms of noise. This is equivalent to having a
dither circuit that is always enabled.
Multichannel Scanning Considerations
All of the VXI-MIO Series modules can scan multiple channels at the
same maximum rate as their single-channel rate; however, you should
pay careful attention to the settling times for each of the modules. Refer
to Appendix A, Specifications, for a complete listing of settling times
for each of the VXI-MIO Series modules.
When scanning among channels at various gains, the settling times may
increase. When the PGIA switches to a higher gain, the signal on the
previous channel may be well outside the new, smaller range. For
instance, suppose a 4 V signal is connected to channel 0 and a 1 mV
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signal is connected to channel 1, and suppose the PGIA is programmed
to apply a gain of one to channel 0 and a gain of 100 to channel 1. When
the multiplexer switches to channel 1 and the PGIA switches to a gain
of 100, the new full-scale range is 100 mV (if the ADC is in unipolar
mode).
The approximately 4 V step from 4 V to 1 mV is 4,000% of the new
full-scale range. For a 12-bit module to settle within 0.012% (120 ppm
or 1/2 LSB) of the 100 mV full-scale range on channel 1, the input
circuitry has to settle to within 0.0003% (3 ppm or 1/80 LSB) of the
4 V step. It may take as long as 100 µs for the circuitry to settle to this
accuracy. For a 16-bit module to settle within 0.0015% (15 ppm or
1 LSB) of the 100 mV full-scale range on channel 1, the input circuitry
has to settle within 0.00004% (0.4 ppm or 1/400 LSB) of the 4 V step.
It may take as long as 200 µs for the circuitry to settle to this accuracy.
In general, this extra settling time is not needed when the PGIA is
switching to a lower gain.
Settling times can also increase when scanning high-impedance signals
due to a phenomenon called charge injection, where the analog input
multiplexer injects a small amount of charge into each signal source
when that source is selected. If the impedance of the source is not low
enough, the effect of the charge—a voltage error—will not have
decayed by the time the ADC samples the signal. For this reason, you
should keep source impedances under 1 kΩ to perform high-speed
scanning.
Multichannel scanning is not recommended unless sampling rates are
low enough or it is necessary to sample several signals as near to
simultaneously as possible. Single-channel scanning yields more
accurate settling times. The data is much more accurate and
channel-to-channel independent if you acquire data from each channel
independently (for example, 100 points from channel 0, then 100 points
from channel 1, then 100 points from channel 2, and so on).
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Analog Output
♦
♦
VXI-MIO-64E-1
This module supplies two channels of analog output voltage at the
I/O connector. The reference and range for the analog output
circuitry is software-selectable. The reference can be either internal
or external, whereas the range can be either bipolar or unipolar.
VXI-MIO-64XE-10
This module supplies two channels of analog output voltage at the
I/O connector. The range is bipolar or unipolar.
Analog Output Reference Selection
♦
VXI-MIO-64E-1
You can connect each D/A converter (DAC) to this module’s
internal reference of 10 V or to the external reference signal
connected to the external reference (EXTREF) pin on the I/O
connector. This signal applied to EXTREF should be between -10
and +10 V. You do not need to configure both channels for the
same mode.
Analog Output Polarity Selection
Selecting a bipolar range for a particular DAC means that any data
written to that DAC will be interpreted as two’s complement format. In
two’s complement mode, data values written to the analog output
channel can be either positive or negative. If you select unipolar range,
data is interpreted in straight binary format. In straight binary mode,
data values written to the analog output channel range must be positive.
♦
VXI-MIO-64E-1
You can configure each analog output channel for either unipolar
or bipolar output. A unipolar configuration has a range of 0 to V
ref
at the analog output. A bipolar configuration has a range of -V to
ref
+V at the analog output. V is the voltage reference used by
ref
ref
the DACs in the analog output circuitry and can be either the
+10 V onboard reference or an externally supplied reference
between -10 and +10 V. You do not need to configure both
channels for the same range.
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♦
VXI-MIO-64XE-10
You can configure each analog output channel for either unipolar
or bipolar output. A unipolar configuration has a range of 0 to 10 V
at the analog output. A bipolar configuration has a range of -10 to
+10 V at the analog output. You do not need to configure both
channels for the same range.
Analog Output Reglitch Selection
♦
VXI-MIO-64E-1
In normal operation, a DAC output will glitch whenever it is
updated with a new value. The glitch energy differs from code to
code and appears as distortion in the frequency spectrum. Each
analog output of this module contains a reglitch circuit that
generates uniform glitch energy at every code rather than large
glitches at the major code transitions. This uniform glitch energy
appears as a multiple of the update rate in the frequency spectrum.
Notice that this reglitch circuit does not eliminate the glitches; it
only makes them more uniform in size. Reglitching is normally
disabled at startup and can be independently enabled for each
channel through software.
♦
VXI-MIO-64XE-10
This module does not require reglitch selection.
Analog Trigger
In addition to supporting internal software triggering and external
digital triggering to initiate a data acquisition sequence, the
VXI-MIO-64E-1 and VXI-MIO-64XE-10 also support analog
triggering. You can configure the analog trigger circuitry to accept
either a direct analog input from the PFI0/TRIG1 pin on the I/O
connector or a postgain signal from the output of the PGIA, as shown in
Figure 3-3. The trigger-level range for the direct analog channel is
±10 V in 78 mV steps for the VXI-MIO-64E-1, and ±10 V in 4.9 mV
steps for theVXI-MIO-64XE-10. The range for the post-PGIA trigger
selection is simply the full-scale range of the selected channel, and the
resolution is that range divided by 256 for the VXI-MIO-64E-1, and
divided by 4,096 for the VXI-MIO-64XE-10.
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Note:
The PFI0/TRIG1 pin is a high-impedance input. Therefore, it is
susceptible to cross-talk from adjacent pins, which can result in false
triggering when the pin is left unconnected. To avoid false triggering, make
sure this pin is connected to a low-impedance signal source (less than
10 kΩ source impedance) if you plan to enable this input via software.
+
-
Analog
Input
PGIA
ADC
Channels
Analog
Trigger
Circuit
DAQ-STC
Mux
PFI0/TRIG1
Figure 3-3. Analog Trigger Block Diagram
There are five analog triggering modes available, as shown in
Figures 3-4 through 3-8. You can set lowValue and highValue
independently in software.
In below-low-level analog triggering mode, the trigger is generated
when the signal value is less than lowValue. HighValue is unused.
lowValue
Trigger
Figure 3-4. Below-Low-Level Analog Triggering Mode
In above-high-level analog triggering mode, the trigger is generated
when the signal value is greater than highValue. LowValue is unused.
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highValue
Trigger
Figure 3-5. Above-High-Level Analog Triggering Mode
In inside-region analog triggering mode, the trigger is generated when
the signal value is between the lowValue and the highValue.
highValue
lowValue
Trigger
Figure 3-6. Inside-Region Analog Triggering Mode
In high-hysteresis analog triggering mode, the trigger is generated
when the signal value is greater than highValue, with the hysteresis
specified by lowValue.
highValue
lowValue
Trigger
Figure 3-7. High-Hysteresis Analog Triggering Mode
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In low-hysteresis analog triggering mode, the trigger is generated when
the signal value is less than lowValue, with the hysteresis specified by
highValue.
highValue
lowValue
Trigger
Figure 3-8. Low-Hysteresis Analog Triggering Mode
The analog trigger circuit generates an internal digital trigger based on
the analog input signal and the user-defined trigger levels. This digital
trigger can be used by any of the timing sections of the DAQ-STC,
including the analog input, analog output, and general-purpose
counter/timer sections. For example, the analog input section can be
configured to acquire n scans after the analog input signal crosses a
specific threshold. As another example, the analog output section can be
configured to update its outputs whenever the analog input signal
crosses a specific threshold.
Digital I/O
The VXI-MIO Series modules contain eight lines of digital I/O for
general-purpose use. You can individually configure each line through
software for either input or output. At system startup and reset, the
digital I/O ports are all high impedance.
The hardware up/down control for general-purpose counters 0 and 1 are
connected onboard to DIO6 and DIO7, respectively. Thus, you can use
DIO6 and DIO7 to control the general-purpose counters. The up/down
control signals are input only and do not affect the operation of the DIO
lines.
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Chapter 3 Hardware Overview
Timing Signal Routing
The DAQ-STC provides a very flexible interface for connecting timing
signals to other modules or external circuitry. Your VXI-MIO Series
module uses the VXIbus trigger for interconnecting timing signals
between modules and the Programmable Function Input (PFI) pins on
the I/O connector for connecting to external circuitry. These
connections are designed to enable the VXI-MIO Series module to both
control and be controlled by other modules and circuits.
There are a total of 13 timing signals internal to the DAQ-STC that can
be controlled by an external source. These timing signals can also be
controlled by signals generated internally to the DAQ-STC, and these
selections are fully software-configurable. For example, the signal
routing multiplexer for controlling the CONVERT* signal is shown in
Figure 3-9.
VXI TTL Trigger <0..4>
VXI ECL Trigger <0..1>
CONVERT*
PFI<0..9>
Sample Interval Counter TC
GPCTR0_OUT
Figure 3-9. CONVERT* Signal Routing
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This figure shows that CONVERT* can be generated from a number of
sources, including the external signals VXI TTL Trig<0..4>,
VXI ECL Trig<0..1>, and PFI<0..9>, and the internal signals Sample
Interval Counter TC and GPCTR0_OUT.
Many of these timing signals are also available as outputs on the
VXIbus trigger, as indicated in the VXIbus Triggers section later in this
chapter, and on the PFI pins, as indicated in Chapter 4, Signal
Connections.
Programmable Function Inputs
The 10 PFIs are connected to the signal routing multiplexer for each
timing signal, and software can select one of the PFIs as the external
source for a given timing signal. It is important to note that any of the
PFIs can be used as an input by any of the timing signals and that
multiple timing signals can use the same PFI simultaneously. This
flexible routing scheme reduces the need to change physical
connections to the I/O connector for different applications.
You can also individually enable each of the PFI pins to output a
specific internal timing signal. For example, if you need the UPDATE*
signal as an output on the I/O connector, your software can turn on the
output driver for the PFI5/UPDATE* pin.
Module and Timebase
Many functions that the VXI-MIO Series modules perform require a
frequency timebase to generate the necessary timing signals for
controlling A/D conversions, DAC updates, or general-purpose signals
at the I/O connector.
A VXI-MIO Series module can use either its internal 20 MHz timebase,
which is phase-locked to CLK10 on the VXIbus, or a timebase received
over a VXIbus trigger line. In addition, if you configure the module to
use the internal timebase, you can also program the module to drive its
internal timebase over the VXIbus trigger line to another module that is
programmed to receive this timebase signal. This clock source, whether
local or from the VXIbus trigger line, is used directly by the module as
the primary frequency source. The default configuration at startup is to
use the internal timebase without driving the VXIbus trigger line
timebase signal. This timebase is software-selectable.
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Chapter 3 Hardware Overview
VXIbus Triggers
The VXI-MIO Series modules can use up to seven of the 10 VXIbus
trigger lines to coordinate sampling and/or triggering across multiple
modules.
When using NI-DAQ software, the VXIbus trigger lines are
functionally equivalent to RTSI bus trigger lines.
DAQ-STC
TRIG1
TRIG2
CONVERT*
UPDATE*
WFTRIG
GPCTR0_SOURCE
TTL Triggers
GPCTR0_GATE
GPCTR0_OUT
5
STARTSCAN
ECL Triggers
AIGATE
SISOURCE
2
UISOURCE
GPCTR1_SOURCE
GPCTR1_GATE
RTSI_OSC (20 MHz)
Figure 3-10. VXIbus Trigger Utilization
Refer to the Timing Connections section of Chapter 4 for a description
of the signals shown in Figure 3-10.
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Chapter
4
Signal Connections
This chapter describes how to make input and output signal connections
to your VXI-MIO Series module via the module I/O connector.
The VXI-MIO-64E-1 and VXI-MIO-64XE-10 I/O connector has
96 pins that you can connect to 68-pin accessories with the SH966868
shielded cable. Refer to Appendix B, Optional Cable Connector
Descriptions, for more information.
I/O Connector
Figure 4-1 shows the 96-pin I/O connector pin assignments on the
VXI-MIO-64E-1 and VXI-MIO-64XE-10. A signal description follows
the connector pinouts.
Warning: Connections that exceed any of the maximum ratings of input or output
signals on the VXI-MIO Series modules can damage the module.
Maximum input ratings for each signal are given in Tables 4-1 and 4-2 in
the Protection column. National Instruments is NOT liable for any damages
resulting from signal connections that exceed these maximum ratings.
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Chapter 4 Signal Connections
A
B
C
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
PFI9/GPCTR0_GATE
GPCTR0_OUT
PFI7/STARTSCAN
GPCTR1_OUT
PFI2/CONVERT*
EXTSTROBE*
DGND
FREQ_OUT
PFI8/GPCTR0_SOURCE
PFI5/UPDATE*
PFI3/GPCTR1_SOURCE
PFI0/TRIG1
PFI6/WFTRIG
PFI4/GPCTR1_GATE
PFI1/TRIG2
+5 V
DIO7
SCANCLK
DIO2
DIO6
DIO3
DIO4
DIO1
DIO5
DAC0OUT
ACH0
AOGND
EXTREF2
DIO0
DAC1OUT
ACH9
ACH3
ACH1
ACH10
AISENSE3
ACH5
ACH8
ACH2
ACH4
ACH11
ACH12
ACH6
ACH13
ACH7
ACH14
AIGND
ACH17
ACH26
ACH20
ACH29
ACH23
ACH40
ACH34
ACH43
ACH44
ACH16
ACH25
ACH19
ACH28
ACH22
ACH31
ACH33
ACH42
AISENSE21
ACH37
ACH15
ACH24
ACH18
ACH27
ACH21
ACH30
ACH32
ACH41
ACH35
ACH36
8
8
8
ACH46
ACH48
ACH57
ACH51
ACH60
ACH54
ACH63
7
ACH38
ACH47
ACH49
ACH58
ACH52
ACH61
ACH55
7
ACH45
ACH39
ACH56
ACH50
ACH59
ACH53
ACH62
7
6
6
6
5
5
5
4
4
4
3
3
3
2
2
2
1
1
1
1 SENSE for ACH16 through ACH63
2 This pin is not connected on the VXI-MIO-64XE-10
3 SENSE for ACH0 through ACH15
Figure 4-1. I/O Connector Pin Assignment for the VXI-MIO-64E-1 and
VXI-MIO-64XE-10
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Chapter 4 Signal Connections
I/O Connector Signal Descriptions
Signal Name
Reference
Direction
Description
AIGND
—
—
Analog Input Ground—These pins are the reference point
for single-ended measurements and the bias current return
point for differential measurements. All three ground
references—AIGND, AOGND, and DGND—are connected
together on your VXI-MIO Series module.
ACH<0..15>
ACH<16..63>
AIGND
AIGND
Input
Input
Analog Input Channels 0 through 15—Each channel pair,
ACH<i, i+8> (i = 0..7), can be configured as either one
differential input or two single-ended inputs.
Analog Input Channels 16 through 63—Each channel pair,
ACH<i, i+8> (i = 16..23, 32..39, 48..55), can be configured
as either one differential input or two single-ended inputs.
AISENSE
AISENSE2
DAC0OUT
DAC1OUT
EXTREF
AIGND
AIGND
AOGND
AOGND
AOGND
Input
Analog Input Sense—This pin serves as the reference node
for any of channels ACH <0..15> in NRSE configuration.
Input
Analog Input Sense—This pin serves as the reference node
for any of channels ACH <16..63> in NRSE configuration.
Output
Output
Input
Analog Channel 0 Output—This pin supplies the voltage
output of analog output channel 0.
Analog Channel 1 Output—This pin supplies the voltage
output of analog output channel 1.
External Reference—This is the external reference input for
the analog output circuitry. This pin is not available on the
VXI-MIO-64XE-10.
AOGND
DGND
—
—
—
—
Analog Output Ground—The analog output voltages are
referenced to this node. All three ground references—
AIGND, AOGND, and DGND—are connected together on
your VXI-MIO Series module.
Digital Ground—This pin supplies the reference for the
digital signals at the I/O connector as well as the +5 VDC
supply. All three ground references—AIGND, AOGND,
and DGND—are connected together on your
VXI-MIO Series module.
DIO<0..7>
+5 V
DGND
DGND
Input or
Output
Digital I/O signals—DIO6 and 7 can control the up/down
signal of general-purpose counters 0 and 1, respectively.
Output
+5 VDC Source—These pins are fused for up to 1 A of
+5 V supply. The circuit breaker is self-resetting.
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Chapter 4 Signal Connections
Signal Name
Reference
Direction
Description (Continued)
SCANCLK
DGND
Output
Scan Clock—This pin pulses once for each A/D conversion
in the scanning modes when enabled. The low-to-high edge
indicates when the input signal can be removed from the
input or switched to another signal.
EXTSTROBE*
PFI0/TRIG1
DGND
DGND
Output
Input
External Strobe—This output can be toggled under software
control to latch signals or trigger events on external devices.
PFI0/Trigger 1—As an input, this is either one of the PFIs or
the source for the hardware analog trigger. PFI signals are
explained in the Timing Connections section later in this
chapter. The hardware analog trigger is explained in the
Analog Trigger section in Chapter 2.
Output
As an output, this is the TRIG1 signal. In posttrigger data
acquisition sequences, a low-to-high transition indicates the
initiation of the acquisition sequence. In pretrigger
applications, a low-to-high transition indicates the initiation
of the pretrigger conversions.
PFI1/TRIG2
DGND
Input
PFI1/Trigger 2—As an input, this is one of the PFIs.
Output
As an output, this is the TRIG2 signal. In pretrigger
applications, a low-to-high transition indicates the initiation
of the posttrigger conversions. TRIG2 is not used in
posttrigger applications.
PFI2/CONVERT*
DGND
DGND
Input
PFI2/Convert—As an input, this is one of the PFIs.
Output
As an output, this is the CONVERT* signal. A high-to-low
edge on CONVERT* indicates that an A/D conversion is
occurring.
PFI3/GPCTR1_SOURCE
Input
PFI3/Counter 1 Source—As an input, this is one of the
PFIs.
Output
As an output, this is the GPCTR1_SOURCE signal. This
signal reflects the actual source connected to the
general-purpose counter 1.
PFI4/GPCTR1_GATE
DGND
DGND
Input
PFI4/Counter 1 Gate—As an input, this is one of the PFIs.
Output
As an output, this is the GPCTR1_GATE signal. This signal
reflects the actual gate signal connected to the
general-purpose counter 1.
GPCTR1_OUT
Output
Counter 1 Output—This output is from the general-purpose
counter 1 output.
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Chapter 4 Signal Connections
Signal Name
Reference
Direction
Input
Description (Continued)
PFI5/UPDATE*
DGND
PFI5/Update—As an input, this is one of the PFIs.
Output
As an output, this is the UPDATE* signal. A high-to-low
edge on UPDATE* indicates that the analog output primary
group is being updated.
PFI6/WFTRIG
DGND
DGND
DGND
DGND
Input
PFI6/Waveform Trigger—As an input, this is one of the
PFIs.
Output
As an output, this is the WFTRIG signal. In timed analog
output sequences, a low-to-high transition indicates the
initiation of the waveform generation.
PFI7/STARTSCAN
PFI8/GPCTR0_SOURCE
PFI9/GPCTR0_GATE
Input
PFI7/Start of Scan—As an input, this is one of the PFIs.
Output
As an output, this is the STARTSCAN signal. This pin
pulses once at the start of each analog input scan in the
interval scan. A low-to-high transition indicates the start of
the scan.
Input
PFI8/Counter 0 Source—As an input, this is one of the
PFIs.
Output
As an output, this is the GPCTR0_SOURCE signal. This
signal reflects the actual source connected to the
general-purpose counter 0.
Input
PFI9/Counter 0 Gate—As an input, this is one of the PFIs.
Output
As an output, this is the GPCTR0_GATE signal. This signal
reflects the actual gate signal connected to the
general-purpose counter 0.
GPCTR0_OUT
FREQ_OUT
DGND
DGND
Output
Output
Counter 0 Output—This output is from the general-purpose
counter 0 output.
Frequency Output—This output is from the frequency
generator output.
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Chapter 4 Signal Connections
Table 4-1 shows the I/O signal summary for the VXI-MIO-64E-1.
Table 4-1. VXI-MIO-64E-1 I/O Signal Summary
Signal Name
Drive Impedance
Input/
Protection
(Volts)
Power On/Off
Source
(mA at V)
Sink
(mA at
V)
Rise
Time
(ns)
Bias
Output
ACH<0..63>
AI
AI
100 GΩ
in parallel
with
25/15
25/15
—
—
—
—
—
—
±200 pA
100 pF
AISENSE, AISENSE2
100 GΩ
in parallel
with
—
—
±200 pA
100 pF
AIGND
AI
—
—
—
—
—
DAC0OUT
AO
0.1 Ω
Short-circuit
to ground
5 at 10 V
5 at -10 V
20
V/µs
DAC1OUT
AO
0.1 Ω
Short-circuit
to ground
5 at 10 V
5 at -10 V
20
V/µs
—
EXTREF
AOGND
DGND
+5 V
AO
AO
DO
DO
10 kΩ
—
25/15
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
0.1Ω
Short-circuit
to ground
1 A at 5 V
1
2
DIO<0..7>
DIO
DO
DO
—
—
—
5.5 V
—
13 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
24 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
1.1
1.5
1.5
1.5
1.5
1.5
1.5
1.5
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
SCANCLK
EXTSTROBE*
PFI0/TRIG1
—
ADIO 10 kΩ
5.5 V
5.5 V
5.5 V
5.5 V
5.5 V
PFI1/TRIG2
DIO
DIO
DIO
DIO
—
—
—
—
PFI2/CONVERT*
PFI3/GPCTR1_SOURCE
PFI4/GPCTR1_GATE
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Chapter 4 Signal Connections
Table 4-1. VXI-MIO-64E-1 I/O Signal Summary (Continued)
Signal Name
Drive Impedance
Input/
Protection
(Volts)
Power On/Off
Source
(mA at V)
Sink
(mA at
V)
Rise
Time
(ns)
Bias
Output
GPCTR1_OUT
DO
—
—
—
—
—
—
—
—
—
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
1.5
1.5
1.5
1.5
1.5
1.5
1.5
1.5
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
PFI5/UPDATE*
DIO
DIO
DIO
DIO
DIO
DO
5.5 V
5.5 V
5.5 V
5.5 V
5.5 V
—
PFI6/WFTRIG
PFI7/STARTSCAN
PFI8/GPCTR0_SOURCE
PFI9/GPCTR0_GATE
GPCTR0_OUT
FREQ_OUT
DO
—
AI = Analog Input
AO = Analog Output
DIO = Digital Input/Output
DO = Digital Output
pu = pullup
ADIO = Analog/Digital Input/Output
1
DIO <6..7> are also pulled down with a 50 kΩ resistor.
2
Also pulled down with a 10 kΩ resistor.
Note: The tolerance on the 50 kΩ pullup and pulldown resistors is very large. Actual value may range between
17 and 100 kΩ.
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Chapter 4 Signal Connections
Table 4-2 shows the I/O signal summary for the VXI-MIO-64XE-10.
Table 4-2. VXI-MIO-64XE-10 I/O Signal Summary
Signal Name
Drive Impedance
Input/
Protection
(Volts)
Power On/Off
Source
(mA at V)
Sink
(mA at V) Time
(ns)
Rise
Bias
Output
ACH<0..63>
AI
AI
100 GΩ in
parallel
with
25/15
25/15
—
—
—
—
—
—
—
—
—
±1 nA
100 pF
AISENSE
100 GΩ in
parallel
with
±1 nA
100 pF
AIGND
AI
—
—
—
—
DAC0OUT
AO
0.1 Ω
Short-circuit 5 at 10 V
to ground
5 at -10 V
5
V/µs
DAC1OUT
AO
0.1 Ω
Short-circuit 5 at 10 V
to ground
5 at -10 V
5
V/µs
—
AOGND
DGND
+5 V
AO
DO
DO
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
0.1 Ω
Short-circuit 1A
to ground
DIO<0..7>
DIO
DO
—
—
—
—
—
—
—
—
—
5.5 V
—
13 at (4.6 V)
24 at 0.4 1.1
50 kΩ pu
50 kΩ pu
50 kΩ pu
4.75 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
SCANCLK
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
1.5
1.5
1.5
1.5
1.5
1.5
1.5
1.5
EXTSTROBE*
PFI0/TRIG1
DO
—
DIO
DIO
DIO
DIO
DIO
DO
5.5 V
5.5 V
5.5 V
5.5 V
5.5 V
—
PFI1/TRIG2
PFI2/CONVERT*
PFI3/GPCTR1_SOURCE
PFI4/GPCTR1_GATE
GPCTR1_OUT
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Chapter 4 Signal Connections
Table 4-2. VXI-MIO-64XE-10 I/O Signal Summary (Continued)
Signal Name
Drive Impedance
Input/
Protection
(Volts)
Power On/Off
Source
(mA at V)
Sink
(mA at V) Time
(ns)
Rise
Bias
Output
PFI5/UPDATE*
DIO
DIO
DIO
DIO
DIO
DO
—
—
—
—
—
—
—
5.5 V
5.5 V
5.5 V
5.5 V
5.5 V
—
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
3.5 at (4.6 V)
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
5 at 0.4
1.5
1.5
1.5
1.5
1.5
1.5
1.5
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
50 kΩ pu
PFI6/WFTRIG
PFI7/STARTSCAN
PFI8/GPCTR0_SOURCE
PFI9/GPCTR0_GATE
GPCTR0_OUT
FREQ_OUT
DO
—
AI = Analog Input
AO = Analog Output
DIO = Digital Input/Output
DO = Digital Output
pu = pullup
Note: The tolerance on the 50 kΩ pullup and pulldown resistors is very large. Actual value may range between
17 and 100 kΩ.
Analog Input Signal Connections
The VXI-MIO-64E-1 and VXI-MIO-64XE-10 analog input signals
are ACH<0..63>, AISENSE, AISENSE2, and AIGND. The
ACH<0..63> signals are tied to the 64 analog input channels of
both modules. In single-ended mode, signals connected to
ACH<0..63> are routed to the positive input of both modules. In
differential mode, signals connected to ACH<0..7, 16..23, 32..39,
48..55> are routed to the positive input of the PGIA, and signals
connected to ACH<8..15, 24..31, 40..47, 56..63> are routed to the
negative input of the PGIA.
Warning: Exceeding the differential and common-mode input ranges distorts your
input signals. Exceeding the maximum input voltage rating can damage
the VXI-MIO Series module and your VXIbus system. National
Instruments is NOT liable for any damages resulting from such signal
connections. The maximum input voltage ratings are listed in Tables 4-1
and 4-2 in the Protection column.
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In NRSE mode, the AISENSE and AISENSE2 signals are connected
internally to the negative input of the VXI-MIO Series module PGIA
when their corresponding channels are selected. In DIFF and RSE
modes, the AISENSE/AISENSE signals are left unconnected.
AIGND is an analog input common signal that is routed directly to the
ground tie point on the VXI-MIO Series modules. You can use this
signal for a general analog ground tie point to your VXI-MIO Series
module if necessary.
Connection of analog input signals to your VXI-MIO Series module
depends on the configuration of the analog input channels you are using
and the type of input signal source. With the different configurations,
you can use the PGIA in different ways. Figure 4-2 shows a diagram of
your VXI-MIO Series module PGIA.
Instrumentation
Amplifier
Vin+
+
+
PGIA
Vm
Measured
Voltage
Vin-
-
-
Vm = [Vin+ - Vin-]* Gain
Figure 4-2. VXI-MIO Series PGIA
The PGIA applies gain and common-mode voltage rejection and
presents high input impedance to the analog input signals connected to
your VXI-MIO Series module. Signals are routed to the positive and
negative inputs of the PGIA through input multiplexers on the module.
The PGIA converts two input signals to a signal that is the difference
between the two input signals multiplied by the gain setting of the
amplifier. The amplifier output voltage is referenced to the board
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Chapter 4 Signal Connections
ground. Your VXI-MIO Series module ADC measures this output
voltage when it performs A/D conversions.
You must reference all signals to ground either at the signal source or
at the module. If you have a floating source, reference the signal to
ground by using the RSE input mode or the DIFF input configuration
with bias resistors (see the Differential Connections for Nonreferenced
or Floating Signal Sources section later in this chapter). If you have a
grounded source, you should not reference the signal to AIGND. You
can avoid this reference by using DIFF or NRSE input configurations.
Types of Signal Sources
When configuring the input channels and making signal connections,
you must first determine whether the signal sources are floating or
ground-referenced. The following sections describe these two types of
signals.
Floating Signal Sources
A floating signal source is one that is not connected in any way to earth
ground but, rather, has an isolated ground-reference point. Some
examples of floating signal sources are outputs of transformers,
thermocouples, battery-powered devices, optical isolated outputs, and
isolation amplifiers. Tie the ground reference of a floating signal to
your VXI-MIO Series module analog input ground to establish a local
or onboard reference for the signal. Otherwise, the measured input
signal varies as the source floats out of the common-mode input range.
Ground-Referenced Signal Sources
A ground-referenced signal source is one that is connected in some way
to the same ground reference as the VXI-MIO Series module. An
example of this type of signal is a nonisolated output of a signal
generator which is powered from the same power strip as the VXIbus
system.
The difference in ground potential between two instruments connected
to the same power distribution system is typically between 1 and
100 mV but can be much higher if power distribution circuits are not
properly connected. If a grounded signal source is improperly
measured, this difference may appear as an error in the measurement.
The connection instructions for grounded signal sources are designed to
eliminate this ground potential difference from the measured signal.
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Chapter 4 Signal Connections
Input Configurations
You can configure your VXI-MIO Series module for one of three input
modes—NRSE, RSE, or DIFF. The following sections discuss the use
of single-ended and differential measurements and considerations for
measuring both floating and ground-referenced signal sources.
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Chapter 4 Signal Connections
Figure 4-3 summarizes the recommended input configuration for both
types of signal sources.
Signal Source Type
Grounded Signal Source
Floating Signal Source
(Not Connected to Earth Ground)
Examples
Examples
• Plug-in instruments with
nonisolated outputs
• Ungrounded thermocouples
• Signal conditioning with isolated outputs
• Battery devices
Input
ACH(+)
ACH(+)
+
+
+
-
V
1
+
-
V
1
ACH (-)
R
ACH (-)
-
-
Differential
(DIFF)
AIGND
AIGND
See text for information on bias resistors.
NOT RECOMMENDED
ACH
ACH
Referenced
Single-Ended
Ground
+
+
+
+
V
1
V
1
AIGND
-
-
-
-
+
Vg
-
(RSE)
Ground-loop losses, Vg, are added to
measured signal
ACH
ACH
+
+
+
Nonreferenced
Single-Ended
(NRSE)
+
V
1
V
1
AISENSE
AISENSE
R
-
-
-
-
AIGND
AIGND
See text for information on bias resistors.
Figure 4-3. Summary of Analog Input Connections
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Chapter 4 Signal Connections
Differential Connection Considerations (DIFF Input Configuration)
A differential connection is one in which the VXI-MIO Series module
analog input signal has its own reference signal or signal return path.
These connections are available when the selected channel is
configured in DIFF input mode. The input signal is tied to the positive
input of the PGIA, and its reference signal, or return, is tied to the
negative input of the PGIA.
When you configure a channel for differential input, each signal uses
two multiplexer input lines—one for the signal and one for its reference
signal. Therefore, with a differential configuration for every channel,
up to 32 analog input channels are available.
You should use differential input connections for any channel that
meets any of the following conditions:
•
•
The input signal is low level (less than 1 V).
The leads connecting the signal to the VXI-MIO Series module are
greater than 10 ft (3 m).
•
•
The input signal requires a separate ground-reference point or
return signal.
The signal leads travel through noisy environments.
DIFF input connections reduce pick-up noise and increase
common-mode noise rejection. Differential signal connections also
allow input signals to float within the common-mode limits of the
PGIA.
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Chapter 4 Signal Connections
Differential Connections for Ground-Referenced
Signal Sources
Figure 4-4 shows how to connect a ground-referenced signal source to
a channel on a VXI-MIO Series module configured in DIFF input
mode.
ACH<0..7>
Ground-
Referenced
Signal
+
-
Instrumentation
Vs
Source
Amplifier
+
PGIA
+
ACH<8..15>
Measured
Voltage
-
Vm
Common-
Mode
Noise and
Ground
-
+
-
Vcm
Potential
Other Input Multiplexers
AISENSE
AIGND
I/O Connector
Selected Channel in DIFF Configuration
Figure 4-4. Differential Input Connections for Ground-Referenced Signals
With this type of connection, the PGIA rejects both the common-mode
noise in the signal and the ground potential difference between the
signal source and the VXI-MIO Series module ground, shown as V
in Figure 4-4.
cm
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Chapter 4 Signal Connections
Differential Connections for Nonreferenced or
Floating Signal Sources
Figure 4-5 shows how to connect a floating signal source to a channel
on a VXI-MIO Series module configured in DIFF input mode.
ACH<0..7>
Bias
resistors
(see text)
Floating
Signal
Source
+
-
Instrumentation
Amplifier
VS
+
-
PGIA
+
-
ACH<8..15>
Measured
Voltage
Vm
Bias
Current
Return
Paths
Other Input Multiplexers
AISENSE
AIGND
I/O Connector
Selected Channel in DIFF Configuration
Figure 4-5. Differential Input Connections for Nonreferenced Signals
Figure 4-5 shows two bias resistors connected in parallel with the signal
leads of a floating signal source. If you do not use the resistors and the
source is truly floating, the source is not likely to remain within the
common-mode signal range of the PGIA, and the PGIA will saturate,
causing erroneous readings. You must reference the source to AIGND.
The easiest way is simply to connect the positive side of the signal to
the positive input of the PGIA and connect the negative side of the
signal to AIGND as well as to the negative input of the PGIA, without
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Chapter 4 Signal Connections
any resistors at all. This connection works well for DC-coupled sources
with low source impedance (less than 100 Ω).
However, for larger source impedances, this connection leaves the
differential signal path significantly out of balance. Noise that couples
electrostatically onto the positive line does not couple onto the negative
line because it is connected to ground. Hence, this noise appears as a
differential-mode signal instead of a common-mode signal, and so the
PGIA does not reject it. In this case, instead of directly connecting the
negative line to AIGND, connect it to AIGND through a resistor that is
about 100 times the equivalent source impedance. The resistor puts the
signal path nearly in balance, so that about the same amount of noise
couples onto both connections, yielding better rejection of
electrostatically coupled noise. Also, this configuration does not load
down the source (other than the very high input impedance of the
PGIA).
You can fully balance the signal path by connecting another resistor of
the same value between the positive input and AIGND, as shown in
Figure 4-5. This fully-balanced configuration offers slightly better
noise rejection but has the disadvantage of loading the source down
with the series combination (sum) of the two resistors. If, for example,
the source impedance is 2 kΩ and each of the two resistors is 100 kΩ,
the resistors load down the source with 200 kΩ and produce a -1% gain
error.
Both PGIA inputs require a DC path to ground in order for the PGIA to
work. If the source is AC-coupled (capacitively coupled), the PGIA
needs a resistor between the positive input and AIGND. If the source
has low impedance, choose a resistor that is large enough not to
significantly load the source but small enough not to produce
significant input offset voltage as a result of input bias current
(typically 100 kΩ to 1 MΩ). In this case, you can tie the negative input
directly to AIGND. If the source has high output impedance, you should
balance the signal path as previously described using the same value
resistor on both the positive and negative inputs; you should be aware
that there is some gain error from loading down the source.
Refer to Application Note 025, Field Wiring and Noise Considerations
for Analog Signals, for more information.
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Chapter 4 Signal Connections
Single-Ended Connection Considerations
A single-ended connection is one in which the VXI-MIO Series module
analog input signal is referenced to a ground that can be shared with
other input signals. The input signal is tied to the PGIA positive input,
and the ground is tied to the PGIA negative input.
When you configure every channel for single-ended input, up to 64
analog input channels are available.
You can use single-ended input connections for any channel signal that
meets all of the following conditions:
•
•
The input signal is high level (greater than 1 V).
The leads connecting the signal to the VXI-MIO Series module are
less than 10 ft (3 m).
•
The input signal can share a common reference point with other
signals.
DIFF input connections are recommended for greater signal integrity
for any input signal that does not meet the preceding conditions.
You can software-configure the VXI-MIO Series module channels for
two different types of single-ended connections—RSE configuration
and NRSE configuration. The RSE configuration is used for floating
signal sources; in this case, the VXI-MIO Series module provides the
reference ground point for the external signal. The NRSE input
configuration is used for ground-referenced signal sources; in this case,
the external signal supplies its own reference ground point and the
VXI-MIO Series module should not supply one.
In single-ended configurations, more electrostatic and magnetic noise
couples into the signal connections than in differential configurations.
The coupling is the result of differences in the signal path. Magnetic
coupling is proportional to the area between the two signal conductors.
Electrical coupling is a function of how much the electric field differs
between the two conductors.
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Chapter 4 Signal Connections
Single-Ended Connections for Floating Signal
Sources (RSE Configuration)
Figure 4-6 shows how to connect a floating signal source to a channel
on the VXI-MIO Series module configured for RSE mode.
ACH<0..15>
Instrumentation
+
-
Floating
Signal
Source
Amplifier
+
Vs
PGIA
+
-
Other Input Multiplexers
AISENSE
Measured
Voltage
Vm
-
AIGND
I/O Connector
Selected Channel in RSE Configuration
Figure 4-6. Single-Ended Input Connections for Nonreferenced or Floating Signals
Single-Ended Connections for Grounded Signal
Sources (NRSE Configuration)
To measure a grounded signal source with a single-ended configuration,
you must configure your VXI-MIO Series module in the NRSE input
configuration. The signal is then connected to the module’s PGIA
positive input, and the signal local ground reference is connected to the
PGIA negative input. The ground point of the signal should, therefore,
be connected to the AISENSE pin. Any potential difference between the
VXI-MIO Series ground and the signal ground appears as a
common-mode signal at both the positive and negative inputs of the
PGIA, and this difference is rejected by the amplifier. If the input
circuitry of the VXI-MIO module were referenced to ground in this
situation as in the RSE input configuration, this difference in ground
potentials would appear as an error in the measured voltage.
Figure 4-7 shows how to connect a grounded signal source to a channel
on the VXI-MIO Series module configured for NRSE mode.
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Chapter 4 Signal Connections
ACH<0..15>
Instrumentation
Amplifier
+
Ground-
Referenced
Signal
Source
+
-
Vs
PGIA
-
+
-
Input Multiplexers
Measured
Voltage
Vm
+
AISENSE
AIGND
Common-
Mode
Noise
Vcm
and Ground
Potential
-
Selected Channel in NRSE Configuration
I/O Connector
Figure 4-7. Single-Ended Input Connections for Ground-Referenced Signal
Common-Mode Signal Rejection Considerations
Figures 4-6 and 4-7 show connections for signal sources that are
already referenced to some ground point with respect to the
VXI-MIO Series module. In these cases, the PGIA can reject any
voltage caused by ground potential differences between the signal
source and the module. In addition, with differential input connections,
the PGIA can reject common-mode noise pickup in the leads connecting
the signal sources to the module. The PGIA can reject common-mode
+
-
signals as long as V
and V are both within ±11 V of AIGND.
in
in
Analog Output Signal Connections
The analog output signals are DAC0OUT, DAC1OUT, EXTREF, and
AOGND. EXTREF is not available on the VXI-MIO-64XE-10.
DAC0OUT is the voltage output signal for analog output channel 0.
DAC1OUT is the voltage output signal for analog output channel 1.
EXTREF is the external reference input signal for both analog output
channels. You must configure each analog output channel individually
for external reference selection in order for the signal applied at the
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Chapter 4 Signal Connections
external reference input to be used by that channel. If you do not specify
an external reference, the channel will use the internal reference. You
cannot use an external analog output reference with the
VXI-MIO-64XE-10. Analog output configuration options are explained
in the Analog Output section in Chapter 3, Hardware Overview. The
following ranges and ratings apply to the EXTREF input signal:
•
•
Usable input voltage range: ±11 V peak with respect to AOGND
Absolute maximum ratings: ±15 V peak with respect to AOGND
AOGND is the ground reference signal for both analog output channels
and the external reference signal.
Figure 4-8 shows how to make analog output connections and the
external reference input connection to your VXI-MIO Series module.
EXTREF
DAC0OUT
+
-
Channel 0
External
Reference
Signal
+
Vref
(Optional)
VOUT
0
Load
Load
-
-
AOGND
VOUT 1
DAC1OUT
+
Channel 1
Analog Output Channels
VXI-MIO Series Board
Figure 4-8. Analog Output Connections
The external reference signal can be either a DC or an AC signal. The
module multiplies this reference signal by the DAC code (divided by
the full-scale DAC code) to generate the output voltage.
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Chapter 4 Signal Connections
Digital I/O Signal Connections
The digital I/O signals are DIO<0..7> and DGND. DIO<0..7> are the
signals making up the DIO port, and DGND is the ground reference
signal for the DIO port. You can program all lines individually to be
inputs or outputs.
Warning: Exceeding the maximum input voltage ratings, which are listed in
Tables 4-1 and 4-2, can damage the VXI-MIO Series module. National
Instruments is NOT liable for any damages resulting from such incorrect
signal connections.
Figure 4-9 shows signal connections for three typical digital I/O
applications.
+5 V
LED
DIO<7>
DIO<6>
DIO<5>
DIO<4>
DIO<3>
TTL Signal
DIO<2>
DIO<1>
DIO<0>
+5 V
Switch*
DGND
I/O Connector
VXI-MIO Series Board
* Complex switch circuitry is not shown in order to simplify the figure.
Figure 4-9. Digital I/O Connections
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Chapter 4 Signal Connections
Figure 4-9 shows DIO<0, 2..3, 5..6> configured for digital input and
DIO<1, 4, 7> configured for digital output. Digital input applications
include receiving TTL signals and sensing external device states such
as the state of the switch. Digital output applications include sending
TTL signals and driving external devices such as the LED.
Power Connections
One pin on the I/O connector supplies +5 V from the VXIbus power
supply via a self-resetting fuse. The fuse will reset automatically after
you remove the overcurrent condition. These pins are referenced to
DGND and can be used to power external digital circuitry.
•
Power rating +4.65 to +5.25 VDC at 1 A
Warning: Under no circumstances should you connect these +5 V power pins directly
to analog or digital ground or to any other voltage source on the
VXI-MIO Series module or any other device. Doing so can damage the
VXI-MIO Series module and your device. National Instruments is NOT
liable for damages resulting from such a connection.
Timing Connections
Warning: Exceeding the maximum input voltage ratings, which are listed in
Tables 4-1 and 4-2, can damage the VXI-MIO Series module. National
Instruments is NOT liable for any damages resulting from incorrect signal
connections.
All external control over the VXI-MIO module timing is routed through
the 10 programmable function input signals labeled PFI<0..9>. These
signals are explained in detail in the Programmable Function Input
Connections section in this chapter. These PFI signals are bidirectional;
as output signals they are not programmable and reflect the state of
many data acquisition, waveform generation, and general-purpose
timing signals. There are five other dedicated output lines for the
remainder of the timing signals. As input signals, the PFI signals are
programmable and can control any data acquisition, waveform
generation, and general-purpose timing signals.
The data acquisition signals are explained in the Data Acquisition
Timing Connections section later in this chapter. The waveform
generation signals are explained in the Waveform Generation Timing
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Connections section later in this chapter. The general-purpose timing
signals are explained in the General-Purpose Timing Signal
Connections section later in this chapter.
All digital timing connections are referenced to DGND. This reference
is demonstrated in Figure 4-10, which shows how to connect an external
TRIG1 source and an external CONVERT* source to two of the
VXI-MIO Series module PFI pins.
PFI0/TRIG1
PFI2/CONVERT*
TRIG1
Source
CONVERT*
Source
DGND
I/O Connector
VXI-MIO Series Board
Figure 4-10. Timing I/O Connections
Programmable Function Input Connections
There are a total of 13 internal timing signals that you can externally
control from the PFI pins. The source for each of these signals is
software-selectable from any of the PFIs when you want external
control. This flexible routing scheme reduces the need to change the
physical wiring to the module I/O connector for different applications
requiring alternative wiring.
You can individually enable each of the PFI pins to output a specific
internal timing signal. For example, if you need the CONVERT* signal
as an output on the I/O connector, your software can turn on the output
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Chapter 4 Signal Connections
driver for the PFI2/CONVERT* pin. Be careful not to drive a PFI signal
externally when it is configured as an output.
As an input, you can individually configure each PFI for edge or level
detection and also for polarity selection. You can use the polarity
selection for any of the 13 timing signals, but the edge or level detection
will depend upon the particular timing signal being controlled. The
detection requirements for each timing signal are listed in the section
that discusses that individual signal.
In edge-detection mode, a minimum pulse width of 10 ns is required.
This applies for both rising-edge and falling-edge polarity settings.
There is no maximum pulse-width requirement in edge-detection mode.
In level-detection mode, there are no minimum or maximum
pulse-width requirements imposed by the PFIs themselves, but limits
may be imposed by the particular timing signal being controlled. These
requirements are listed later in this chapter.
Data Acquisition Timing Connections
The data acquisition timing signals are SCANCLK, EXTSTROBE*,
TRIG1, TRIG2, STARTSCAN, CONVERT*, AIGATE, and
SISOURCE.
Posttriggered data acquisition allows you to view only data that is
acquired after a trigger event is received. A typical posttriggered data
acquisition sequence is shown in Figure 4-11. Pretriggered data
acquisition allows you to view data that is acquired before the trigger of
interest in addition to data acquired after the trigger. Figure 4-12 shows
a typical pretriggered data acquisition sequence. The description for
each signal shown in these figures is included later in this chapter.
TRIG1
STARTSCAN
CONVERT*
Scan Counter
4
3
2
1
0
Figure 4-11. Typical Posttriggered Acquisition
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Chapter 4 Signal Connections
TRIG1
Don't Care
TRIG2
STARTSCAN
CONVERT*
Scan Counter
3
2
1
0
2
2
2
1
0
Figure 4-12. Typical Pretriggered Acquisition
SCANCLK Signal
SCANCLK is an output-only signal that generates a pulse with the
leading edge occurring approximately 50 to 100 ns after an A/D
conversion begins. The polarity of this output is software selectable but
is typically configured so that a low-to-high leading edge can clock
external analog input multiplexers indicating when the input signal has
been sampled and can be removed. This signal has a 400 to 500 ns pulse
width and is software-enabled. Figure 4-13 shows the timing for the
SCANCLK signal.
CONVERT*
td
SCANCLK
tw
td
= 50 to 100 ns
= 400 to 500 ns
tw
Figure 4-13. SCANCLK Signal Timing
EXTSTROBE* Signal
EXTSTROBE* is an output-only signal that generates either a single
pulse or a sequence of eight pulses in the hardware-strobe mode. An
external device can use this signal to latch signals or to trigger events.
In the single-pulse mode, your software controls the EXTSTROBE*
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Chapter 4 Signal Connections
signal level. A 10 and 1.2 µs clock is available for generating a
sequence of eight pulses in the hardware-strobe mode. Figure 4-14
shows the timing for the hardware-strobe mode EXTSTROBE* signal.
VOH
VOL
t w
t w
t w
= 600 ns or 5 µs
Figure 4-14. EXTSTROBE* Signal Timing
TRIG1 Signal
Any PFI pin can externally input the TRIG1 signal, which is available
as an output on the PFI0/TRIG1 pin.
Refer to Figures 4-11 and 4-12 for the relationship of TRIG1 to the data
acquisition sequence.
As an input, the TRIG1 signal is configured in the edge-detection mode.
You can select any PFI pin as the source for TRIG1 and configure the
polarity selection for either rising or falling edge. The selected edge of
the TRIG1 signal starts the data acquisition sequence for both
posttriggered and pretriggered acquisitions. The VXI-MIO-64E-1 and
VXI-MIO-64XE-10 support analog triggering on the PFI0/TRIG1 pin.
See Chapter 3 for more information on analog triggering.
As an output, the TRIG1 signal reflects the action that initiates a data
acquisition sequence. This is true even if the acquisition is being
externally triggered by another PFI. The output is an active high pulse
with a pulse width of 50 to 100 ns. This signal is set to input (High-Z)
at startup.
Figures 4-15 and 4-16 show the input and output timing requirements
for the TRIG1 signal.
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Chapter 4 Signal Connections
tw
Rising-edge
polarity
Falling-edge
polarity
tw
= 10 ns minimum
Figure 4-15. TRIG1 Input Signal Timing
tw
tw
= 50-100 ns
Figure 4-16. TRIG1 Output Signal Timing
The module also uses the TRIG1 signal to initiate pretriggered data
acquisition operations. In most pretriggered applications, the
acquisition is started by a software trigger. Refer to the TRIG2 signal
description for a complete description of the use of TRIG1 and TRIG2
in a pretriggered data acquisition operation.
TRIG2 Signal
Any PFI pin can externally input the TRIG2 signal, which is available
as an output on the PFI1/TRIG2 pin.
Refer to Figure 4-12 for the relationship of TRIG2 to the data
acquisition sequence.
As an input, the TRIG2 signal is configured in the edge-detection mode.
You can select any PFI pin as the source for TRIG2 and configure the
polarity selection for either rising or falling edge. The selected edge of
the TRIG2 signal initiates the posttriggered phase of a pretriggered
acquisition sequence. In pretriggered mode, the TRIG1 signal initiates
the data acquisition. The scan counter indicates the minimum number of
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scans before TRIG2 can be recognized. After the scan counter
decrements to zero, it is loaded with the number of posttrigger scans to
acquire while the acquisition continues. The module ignores the TRIG2
signal if it is asserted prior to the scan counter decrementing to zero.
After the selected edge of TRIG2 is received, the module will acquire a
fixed number of scans and the acquisition will stop. This mode acquires
data both before and after receiving TRIG2.
As an output, the TRIG2 signal reflects the posttrigger in a pretriggered
acquisition sequence. This is true even if the acquisition is being
externally triggered by another PFI. The TRIG2 signal is not used in
posttriggered data acquisition. The output is an active high pulse with a
pulse width of 50 to 100 ns. This signal is set to input (High-Z) at
startup.
Figures 4-17 and 4-18 show the input and output timing requirements
for the TRIG2 signal.
tw
Rising-edge
polarity
Falling-edge
polarity
tw
= 10 ns minimum
Figure 4-17. TRIG2 Input Signal Timing
tw
tw
= 50-100 ns
Figure 4-18. TRIG2 Output Signal Timing
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STARTSCAN Signal
Any PFI pin can externally input the STARTSCAN signal, which is
available as an output on the PFI7/STARTSCAN pin.
Refer to Figures 4-11 and 4-12 for the relationship of STARTSCAN to
the data acquisition sequence.
As an input, the STARTSCAN signal is configured in the
edge-detection mode. You can select any PFI pin as the source for
STARTSCAN and configure the polarity selection for either rising or
falling edge. The selected edge of the STARTSCAN signal initiates a
scan. The sample interval counter starts if you select internally triggered
CONVERT*.
As an output, the STARTSCAN signal reflects the actual start pulse that
initiates a scan. This is true even if the starts are being externally
triggered by another PFI. You have two output options. The first is an
active high pulse with a pulse width of 50 to 100 ns, which indicates the
start of the scan. The second action is an active high pulse that
terminates at the start of the last conversion in the scan, which indicates
a scan in progress. STARTSCAN will be deasserted t after the last
off
conversion in the scan is initiated. This signal is set to input (High-Z) at
startup.
Figures 4-19 and 4-20 show the input and output timing requirements
for the STARTSCAN signal.
tw
Rising-edge
polarity
Falling-edge
polarity
tw
= 10 ns minimum
Figure 4-19. STARTSCAN Input Signal Timing
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tw
STARTSCAN
tw = 50-100 ns
a. Start of Scan
Start Pulse
CONVERT*
STARTSCAN
toff
toff = 10 ns minimum
b. Scan in Progress, Two Conversions per Scan
Figure 4-20. STARTSCAN Output Signal Timing
The CONVERT* pulses are masked off until the module generates the
STARTSCAN signal. If you are using internally generated conversions,
the first CONVERT* will appear when the onboard sample interval
counter reaches zero. If you select an external CONVERT*, the first
external pulse after STARTSCAN will generate a conversion. Separate
the STARTSCAN pulses by at least one scan period.
A counter on your VXI-MIO Series module internally generates the
STARTSCAN signal unless you select some external source. This
counter is started by the TRIG1 signal and is stopped either by software
or by the sample counter.
Scans generated by either an internal or external STARTSCAN signal
are inhibited unless they occur within a data acquisition sequence.
Scans occurring within a data acquisition sequence may be gated by
either the hardware (AIGATE) signal or software command register
gate.
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CONVERT* Signal
Any PFI pin can externally input the CONVERT* signal, which is
available as an output on the PFI2/CONVERT* pin.
Refer back to Figures 4-11 and 4-12 for the relationship of CONVERT*
to the data acquisition sequence.
As an input, the CONVERT* signal is configured in the edge-detection
mode. You can select any PFI pin as the source for CONVERT* and
configure the polarity selection for either rising or falling edge. The
selected edge of the CONVERT* signal initiates an A/D conversion.
As an output, the CONVERT* signal reflects the actual convert pulse
that is connected to the ADC. This is true even if the conversions are
being externally generated by another PFI. The output is an active low
pulse with a pulse width of 50 to 100 ns. This signal is set to input
(High-Z) at startup.
Figures 4-21 and 4-22 show the input and output timing requirements
for the CONVERT* signal.
tw
Rising-edge
polarity
Falling-edge
polarity
tw
= 10 ns minimum
Figure 4-21. CONVERT* Input Signal Timing
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tw
tw
= 50-100 ns
Figure 4-22. CONVERT* Output Signal Timing
The ADC switches to hold mode within 60 ns of the selected edge. This
hold-mode delay time is a function of temperature and does not vary
from one conversion to the next. Separate the CONVERT* pulses by at
least one conversion period.
The sample interval counter on the VXI-MIO Series module normally
generates the CONVERT* signal unless you select some external
source. The STARTSCAN signal starts the counter and the counter
continues to count down and reload itself until the scan is finished. It
then reloads itself in readiness for the next STARTSCAN pulse.
A/D conversions generated by either an internal or external
CONVERT* signal are inhibited unless they occur within a data
acquisition sequence. Scans occurring within a data acquisition
sequence may be gated by either the hardware (AIGATE) signal or
software command register gate.
AIGATE Signal
Any PFI pin can externally input the AIGATE signal, which is not
available as an output on the I/O connector. The AIGATE signal can
mask off scans in a data acquisition sequence. You can configure the
PFI pin you select as the source for the AIGATE signal in either the
level-detection or edge-detection mode. You can configure the polarity
selection for the PFI pin for either active high or active low.
In the level-detection mode if AIGATE is active, the STARTSCAN
signal is masked off and no scans can occur. In the edge-detection
mode, the first active edge disables the STARTSCAN signal, and the
second active edge enables STARTSCAN.
The AIGATE signal can neither stop a scan in progress nor continue a
previously gated-off scan; in other words, once a scan has started,
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AIGATE does not gate off conversions until the beginning of the next
scan and, conversely, if conversions are being gated off, AIGATE does
not gate them back on until the beginning of the next scan.
SISOURCE Signal
Any PFI pin can externally input the SISOURCE signal, which is not
available as an output on the I/O connector. The onboard scan interval
counter uses the SISOURCE signal as a clock to time the generation of
the STARTSCAN signal. You must configure the PFI pin you select as
the source for the SISOURCE signal in the level-detection mode. You
can configure the polarity selection for the PFI pin for either active high
or active low.
The maximum allowed frequency is 20 MHz, with a minimum pulse
width of 23 ns high or low. There is no minimum frequency limitation.
Either the 20 MHz or 100 kHz internal timebase generates the
SISOURCE signal unless you select some external source. Figure 4-23
shows the timing requirements for the SISOURCE signal.
t p
t w
t w
t p
= 50 ns minimum
= 23 ns minimum
t w
Figure 4-23. SISOURCE Signal Timing
Waveform Generation Timing Connections
The analog group defined for your VXI-MIO Series module is
controlled by WFTRIG, UPDATE*, and UISOURCE.
WFTRIG Signal
Any PFI pin can externally input the WFTRIG signal, which is
available as an output on the PFI6/WFTRIG pin.
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As an input, the WFTRIG signal is configured in the edge-detection
mode. You can select any PFI pin as the source for WFTRIG and
configure the polarity selection for either rising or falling edge. The
selected edge of the WFTRIG signal starts the waveform generation for
the DACs. The update interval (UI) counter is started if you select
internally generated UPDATE*.
As an output, the WFTRIG signal reflects the trigger that initiates
waveform generation. This is true even if the waveform generation is
being externally triggered by another PFI. The output is an active high
pulse with a pulse width of 50 to 100 ns. This signal is set to input
(High-Z) at startup.
Figures 4-24 and 4-25 show the input and output timing requirements
for the WFTRIG signal.
tw
Rising-edge
polarity
Falling-edge
polarity
tw
= 10 ns minimum
Figure 4-24. WFTRIG Input Signal Timing
tw
tw
= 50-100 ns
Figure 4-25. WFTRIG Output Signal Timing
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UPDATE* Signal
Any PFI pin can externally input the UPDATE* signal, which is
available as an output on the PFI5/UPDATE* pin.
As an input, the UPDATE* signal is configured in the edge-detection
mode. You can select any PFI pin as the source for UPDATE* and
configure the polarity selection for either rising or falling edge. The
selected edge of the UPDATE* signal updates the outputs of the DACs.
In order to use UPDATE*, you must set the DACs to posted-update
mode.
As an output, the UPDATE* signal reflects the actual update pulse that
is connected to the DACs. This is true even if the updates are being
externally generated by another PFI. The output is an active low pulse
with a pulse width of 300 to 350 ns. This signal is set to input (High-Z)
at startup.
Figures 4-26 and 4-27 show the input and output timing requirements
for the UPDATE* signal.
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Chapter 4 Signal Connections
tw
Rising-edge
polarity
Falling-edge
polarity
tw
= 10 ns minimum
Figure 4-26. UPDATE* Input Signal Timing
t w
tw
= 300-350 ns
Figure 4-27. UPDATE* Output Signal Timing
The DACs are updated within 100 ns of the leading edge. Separate the
UPDATE* pulses with enough time that new data can be written to the
DAC latches.
The VXI-MIO Series module UI counter normally generates the
UPDATE* signal unless you select some external source. The UI
counter is started by the WFTRIG signal and can be stopped by software
or the internal Buffer Counter.
D/A conversions generated by either an internal or external UPDATE*
signal do not occur when gated by the software command register gate.
UISOURCE Signal
Any PFI pin can externally input the UISOURCE signal, which is not
available as an output on the I/O connector. The UI counter uses the
UISOURCE signal as a clock to time the generation of the UPDATE*
signal. You must configure the PFI pin you select as the source for the
UISOURCE signal in the level-detection mode. You can configure the
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polarity selection for the PFI pin for either active high or active low.
Figure 4-28 shows the timing requirements for the UISOURCE signal.
t p
t w
t w
t p
= 50 ns minimum
= 23 ns minimum
t w
Figure 4-28. UISOURCE Signal Timing
The maximum allowed frequency is 20 MHz, with a minimum pulse
width of 23 ns high or low. There is no minimum frequency limitation.
Either the 20 MHz or 100 kHz internal timebase normally generates the
UISOURCE signal unless you select some external source.
General-Purpose Timing Signal Connections
The general-purpose timing signals are GPCTR0_SOURCE,
GPCTR0_GATE, GPCTR0_OUT, GPCTR0_UP_DOWN,
GPCTR1_SOURCE, GPCTR1_GATE, GPCTR1_OUT,
GPCTR1_UP_DOWN, and FREQ_OUT.
GPCTR0_SOURCE Signal
Any PFI pin can externally input the GPCTR0_SOURCE signal, which
is available as an output on the PFI8/GPCTR0_SOURCE pin.
As an input, the GPCTR0_SOURCE signal is configured in the
edge-detection mode. You can select any PFI pin as the source for
GPCTR0_SOURCE and configure the polarity selection for either
rising or falling edge.
As an output, the GPCTR0_SOURCE signal reflects the actual clock
connected to general-purpose counter 0. This is true even if another PFI
is externally inputting the source clock. This signal is set to input
(High-Z) at startup.
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Figure 4-29 shows the timing requirements for the GPCTR0_SOURCE
signal.
t p
t w
t w
t p
= 50 ns minimum
= 23 ns minimum
t w
Figure 4-29. GPCTR0_SOURCE Signal Timing
The maximum allowed frequency is 20 MHz, with a minimum pulse
width of 23 ns high or low. There is no minimum frequency limitation.
The 20 MHz or 100 kHz timebase normally generates the
GPCTR0_SOURCE signal unless you select some external source.
GPCTR0_GATE Signal
Any PFI pin can externally input the GPCTR0_GATE signal, which is
available as an output on the PFI9/GPCTR0_GATE pin.
As an input, the GPCTR0_GATE signal is configured in the
edge-detection mode. You can select any PFI pin as the source for
GPCTR0_GATE and configure the polarity selection for either rising or
falling edge. You can use the gate signal in a variety of different
applications to perform actions such as starting and stopping the
counter, generating interrupts, saving the counter contents, and so on.
As an output, the GPCTR0_GATE signal reflects the actual gate signal
connected to general-purpose counter 0. This is true even if the gate is
being externally generated by another PFI. This signal is set to input
(High-Z) at startup.
Figure 4-30 shows the timing requirements for the GPCTR0_GATE
signal.
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tw
Rising-edge
polarity
Falling-edge
polarity
tw
= 10 ns minimum
Figure 4-30. GPCTR0_GATE Signal Timing in Edge-Detection Mode
GPCTR0_OUT Signal
This signal is available only as an output on the GPCTR0_OUT pin.
The GPCTR0_OUT signal reflects the terminal count (TC) of
general-purpose counter 0. You have two software-selectable output
options— pulse on TC and toggle output polarity on TC. The output
polarity is software-selectable for both options. This signal is set to
input (High-Z) at startup. Figure 4-31 shows the timing of the
GPCTR0_OUT signal.
TC
GPCTR0_SOURCE
GPCTR0_OUT
(Pulse on TC)
GPCTR0_OUT
(Toggle output on TC)
Figure 4-31. GPCTR0_OUT Signal Timing
GPCTR0_UP_DOWN Signal
This signal can be externally input on the DIO6 pin and is not available
as an output on the I/O connector. The general-purpose counter 0 will
count down when this pin is at a logic low and count up when it is at a
logic high. You can disable this input so that software can control the
up-down functionality and leave the DIO6 pin free for general use.
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Chapter 4 Signal Connections
GPCTR1_SOURCE Signal
Any PFI pin can externally input the GPCTR1_SOURCE signal, which
is available as an output on the PFI3/GPCTR1_SOURCE pin.
As an input, the GPCTR1_SOURCE signal is configured in the
edge-detection mode. You can select any PFI pin as the source for
GPCTR1_SOURCE and configure the polarity selection for either
rising or falling edge.
As an output, the GPCTR1_SOURCE monitors the actual clock
connected to general-purpose counter 1. This is true even if the source
clock is being externally generated by another PFI. This signal is set to
input (High-Z) at startup.
Figure 4-32 shows the timing requirements for the GPCTR1_SOURCE
signal.
t p
t w
t w
t p
= 50 ns minimum
= 23 ns minimum
t w
Figure 4-32. GPCTR1_SOURCE Signal Timing
The maximum allowed frequency is 20 MHz, with a minimum pulse
width of 23 ns high or low. There is no minimum frequency limitation.
The 20 MHz or 100 kHz timebase normally generates the
GPCTR1_SOURCE unless you select some external source.
GPCTR1_GATE Signal
Any PFI pin can externally input the GPCTR1_GATE signal, which is
available as an output on the PFI4/GPCTR1_GATE pin.
As an input, the GPCTR1_GATE signal is configured in edge-detection
mode. You can select any PFI pin as the source for GPCTR1_GATE and
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Chapter 4 Signal Connections
configure the polarity selection for either rising or falling edge. You can
use the gate signal in a variety of different applications to perform such
actions as starting and stopping the counter, generating interrupts,
saving the counter contents, and so on.
As an output, the GPCTR1_GATE signal monitors the actual gate
signal connected to general-purpose counter 1. This is true even if the
gate is being externally generated by another PFI. This signal is set to
input (High-Z) at startup.
Figure 4-33 shows the timing requirements for the GPCTR1_GATE
signal.
tw
Rising-edge
polarity
Falling-edge
polarity
tw
= 10 ns minimum
Figure 4-33. GPCTR1_GATE Signal Timing in Edge-Detection Mode
GPCTR1_OUT Signal
This signal is available only as an output on the GPCTR1_OUT pin.
The GPCTR1_OUT signal monitors the TC module general-purpose
counter 1. You have two software-selectable output options—pulse on
TC and toggle output polarity on TC. The output polarity is software-
selectable for both options. This signal is set to input (High-Z) at
startup. Figure 4-34 shows the timing requirements for the
GPCTR1_OUT signal.
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TC
GPCTR1_SOURCE
GPCTR1_OUT
(Pulse on TC)
GPCTR1_OUT
(Toggle output on TC)
Figure 4-34. GPCTR1_OUT Signal Timing
GPCTR1_UP_DOWN Signal
This signal can be externally input on the DIO7 pin and is not available
as an output on the I/O connector. General-purpose counter 1 counts
down when this pin is at a logic low and counts up at a logic high. This
input can be disabled so that software can control the up-down
functionality and leave the DIO7 pin free for general use. Figure 4-35
shows the timing requirements for the GATE and SOURCE input
signals and the timing specifications for the OUT output signals of your
VXI-MIO Series module.
tsc
tsp
tsp
V
IH
SOURCE
GATE
VIL
tgsu
tgh
V
IH
IL
V
tgw
tout
V
V
OH
OL
OUT
Source Clock Period
Source Pulse Width
Gate Setup Time
Gate Hold Time
tsc
50 ns minimum
23 ns minimum
10 ns minimum
0 ns minimum
10 ns minimum
80 ns maximum
tsp
tgsu
tgh
tgw
tout
Gate Pulse Width
Output Delay Time
Figure 4-35. GPCTR Timing Summary
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The GATE and OUT signal transitions shown in Figure 4-35 are
referenced to the rising edge of the SOURCE signal. This timing
diagram assumes that the counters are programmed to count rising
edges. The same timing diagram, but with the source signal inverted and
referenced to the falling edge of the source signal, would apply when
the counter is programmed to count falling edges.
The GATE input timing parameters are referenced to the signal at the
SOURCE input or to one of the internally generated signals on your
VXI-MIO Series module. Figure 4-35 shows the GATE signal
referenced to the rising edge of a source signal. The gate must be valid
(either high or low) for at least 10 ns before the rising or falling edge of
a source signal for the gate to take effect at that source edge, as shown
by t and t in Figure 4-35. The gate signal is not required to be held
gsu
gh
after the active edge of the source signal.
If an internal timebase clock is used, the gate signal cannot be
synchronized with the clock. In this case, gates applied close to a source
edge take effect either on that source edge or on the next one. This
arrangement results in an uncertainty of one source clock period with
respect to unsynchronized gating sources.
The OUT output timing parameters are referenced to the signal at the
SOURCE input or to one of the internally generated clock signals on the
VXI-MIO Series modules. Figure 4-35 shows the OUT signal
referenced to the rising edge of a source signal. Any OUT signal state
changes occur within 80 ns after the rising or falling edge of the source
signal.
FREQ_OUT Signal
This signal is available only as an output on the FREQ_OUT pin. The
FREQ_OUT signal is the output of the VXI-MIO Series module
frequency generator. The frequency generator is a 4-bit counter that can
divide its input clock by the numbers 1 through 16. The input clock of
the frequency generator is software selectable from the internal
10 MHz and 100 kHz timebases. The output polarity is software
selectable. This signal is set to input (High-Z) at startup.
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Chapter 4 Signal Connections
Field Wiring Considerations
Environmental noise can seriously affect the accuracy of measurements
made with your VXI-MIO Series module if you do not take proper care
when running signal wires between signal sources and the module. The
following recommendations apply mainly to analog input signal routing
to the module, although they also apply to signal routing in general.
Take the following precautions to minimize noise pickup and maximize
measurement accuracy:
•
Use differential analog input connections to reject common-mode
noise.
•
Use individually shielded, twisted-pair wires to connect analog
input signals to the module. With this type of wire, the signals
attached to the CH+ and CH- inputs are twisted together and then
covered with a shield. You then connect this shield only at one
point to the signal source ground. This kind of connection is
required for signals traveling through areas with large magnetic
fields or high electromagnetic interference.
•
Route signals to the module carefully. Keep cabling away from
noise sources. A common noise source in many data acquisition
systems is the video monitor. Separate the monitor from the analog
signals as much as possible.
The following recommendations apply for all signal connections to
your VXI-MIO Series module:
•
Separate VXI-MIO Series module signal lines from high-current or
high-voltage lines. These lines are capable of inducing currents in
or voltages on the VXI-MIO Series module signal lines if they run
in parallel paths at a close distance. To reduce the magnetic
coupling between lines, separate them by a reasonable distance if
they run in parallel, or run the lines at right angles to each other.
•
•
Do not run signal lines through conduits that also contain power
lines.
Protect signal lines from magnetic fields caused by electric motors,
welding equipment, breakers, or transformers by running them
through special metal conduits.
For more information, refer to the application note, Field Wiring and
Noise Consideration for Analog Signals available from National
Instruments.
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Chapter
5
Calibration
This chapter discusses the calibration procedures for your
VXI-MIO Series module. NI-DAQ and the VXIplug&play instrument
drivers include calibration functions for performing all of the steps in
the calibration process.
Calibration refers to the process of minimizing measurement and output
voltage errors by making small circuit adjustments. On the
VXI-MIO Series modules, these adjustments take the form of writing
values to onboard calibration DACs (CalDACs).
Some form of module calibration is required for all but the most
forgiving applications. If you do not perform module calibration, your
signals and measurements could have offset, gain, and linearity errors.
Three levels of calibration are available to you and described in this
chapter. The first level is the fastest, easiest, and least accurate, whereas
the last level is the slowest, most difficult, and most accurate.
Loading Calibration Constants
Your VXI-MIO Series module is factory calibrated before shipment at
approximately 25° C to the levels indicated in Appendix A,
Specifications. The associated calibration constants—the values that
were written to the CalDACs to achieve calibration in the factory—are
stored in the onboard nonvolatile memory (EEPROM). Because the
CalDACs have no memory capability, they do not retain calibration
information when the module is unpowered. Loading calibration
constants refers to the process of loading the CalDACs with the values
stored in the EEPROM. NI-DAQ, the VXIplug&play instrument
drivers, or your application software determine when this is necessary
and do it automatically. If you are not using NI-DAQ, the
VXIplug&play instrument drivers, or your application software, you
must load these values yourself.
In the EEPROM there is a user-modifiable calibration area in addition
to the permanent factory calibration area. This means that you can load
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Chapter 5 Calibration
the CalDACs with values either from the original factory calibration or
from a calibration that you subsequently performed.
This method of calibration is not very accurate because it does not take
into account the fact that the module measurement and output voltage
errors can vary with time and temperature. It is better to self-calibrate
when the module is installed in the environment in which it will be used.
Self-Calibration
Your VXI-MIO Series module can measure and correct for almost all of
its calibration-related errors without any external signal connections.
Your National Instruments software provides a self-calibration method
for you. This self-calibration process, which generally takes less than a
minute, is the preferred method of assuring accuracy in your
application. Initiate self-calibration to ensure that you minimize the
effects of any offset, gain, and linearity drifts, particularly those due to
warmup.
Immediately after self-calibration, the only significant residual
calibration error could be gain error due to time or temperature drift of
the onboard voltage reference. External calibration addresses this error,
which is discussed in the following section. If you are interested
primarily in relative measurements, you can ignore a small amount of
gain error, and self-calibration should be sufficient.
External Calibration
Your VXI-MIO Series module has an onboard calibration reference to
ensure the accuracy of self-calibration. Its specifications are listed in
Appendix A, Specifications. The reference voltage is measured at the
factory and stored in the EEPROM for subsequent self-calibrations.
This voltage is stable enough for most applications, but if you are using
your module at an extreme temperature or if the onboard reference has
not been measured for a year or more, you may wish to externally
calibrate your module.
An external calibration refers to calibrating your module with a known
external reference rather than relying on the onboard reference.
Redetermining the value of the onboard reference is part of this process
and the results can be saved in the EEPROM, so you should not have to
perform an external calibration very often. Externally calibrate your
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Chapter 5 Calibration
module by calling the NI-DAQ or VXIplug&play instrument driver
calibration function.
To externally calibrate your module, be sure to use a very accurate
external reference. The reference should be several times more accurate
than the module itself. For example, to calibrate a 12-bit module, the
external reference should be at least ±0.005% (±50 ppm) accurate. To
calibrate a 16-bit module, the external reference should be at least
±0.001% (±10 ppm) accurate.
Other Considerations
The CalDACs adjust the gain error of each analog output channel by
adjusting the value of the reference voltage supplied to that channel.
This calibration mechanism is designed to work only with the internal
10 V reference. Thus, in general, it is not possible to calibrate the
analog output gain error when using an external reference. In this case,
it is advisable to account for the nominal gain error of the analog output
channel either in software or with external hardware. See Appendix A,
Specifications, for analog output gain error information.
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Appendix
A
Specifications
This appendix lists the specifications of each module in the
VXI-MIO Series. These specifications are typical at 25° C unless
otherwise noted.
VXI-MIO-64E-1
Analog Input
Input Characteristics
Number of channels .......................... 64 single-ended or 32
differential (software selectable)
Type of ADC..................................... Successive approximation
Resolution ......................................... 12 bits, 1 in 4,096
Max sampling rate............................. 1.25 MS/s guaranteed
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Appendix A Specifications for VXI-MIO-64E-1
Input signal ranges ................
Module Gain
(Software
Module Range
(Software Selectable)
Selectable)
Bipolar
Unipolar
0.5
1
±10 V
±5 V
—
0 to 10 V
0 to 5 V
2
±2.5 V
5
±1 V
0 to 2 V
10
20
50
100
±500 mV
±250 mV
±100 mV
±50 mV
0 to 1 V
0 to 500 mV
0 to 200 mV
0 to 100 mV
Input coupling....................................DC
Max working voltage
(signal + common mode).................Each input should remain within
±11 V of ground
Overvoltage protection.......................±25 V powered on, ± 15 V
powered off
Inputs protected .......................... ACH<0..63>, AISENSE,
AISENSE2
FIFO buffer size.................................8,192 S
Data transfers.....................................DMA, interrupts, programmed
I/O
Configuration memory size................512 words
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Appendix A Specifications for VXI-MIO-64E-1
Transfer Characteristics
Relative accuracy ............................. ±0.5 LSB typ dithered, ±1.5 LSB
max undithered
DNL .................................................. ±0.5 LSB typ, ±1.0 LSB max
No missing codes .............................. 12 bits, guaranteed
Offset error
Pregain error after calibration .....±12 µV max
Pregain error before calibration...±2.5 mV max
Postgain error after calibration....±0.5 mV max
Postgain error before calibration .±100 mV max
Gain error (relative to calibration reference)
After calibration (gain = 1) .........±0.02% of reading max
Before calibration .......................±2.5% of reading max
Gain ≠ 1 with gain error
adjusted to 0 at gain = 1 .......±0.02% of reading max
Amplifier Characteristics
Input impedance
Normal powered on.....................100 GΩ in parallel with 100 pF
Powered off ................................1 kΩ min
Overload .....................................1 kΩ min
Input bias current .............................. ±200 pA
Input offset current............................ ±100 pA
CMRR, DC to 60 Hz
Gain = 0.5...................................95 dB
Gain = 1......................................100 dB
Gain ≥ 2......................................106 dB
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Appendix A Specifications for VXI-MIO-64E-1
Dynamic Characteristics
Bandwidth .........................
Small signal (-3 dB) Large signal (1% THD)
1.6 MHz 1 MHz
Settling time for
Gain
Accuracy
full-scale step ....................
±0.012%
±0.024%
±0.098%
(±4 LSB)
(±0.5 LSB) (±1 LSB)
3 µs typ
5 µs max
2 µs typ
3 µs max
All
1.8 µs typ
2 µs max
System noise (LSBrms)
Gain
Noise,
Noise,
(not including quantization).......
dither off
dither on
0.5 to 20
50
0.15
0.3
0.5
0.6
100
0.5
0.7
Crosstalk............................................-70 dB, DC to 100 kHz
Stability
Recommended warm-up time.............15 min
Offset temperature coefficient
Pregain ....................................... ±5 µV/°C
Postgain...................................... ±240 µV/°C
Gain temperature coefficient..............±20 ppm/°C
Onboard calibration reference
Level .......................................... 5.000 V (±0.5 mV) (actual value
stored in EEPROM)
Temperature coefficient.............. ±0.6 ppm/°C max
Long-term stability ..................... ±6 ppm/
1,000 h
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Appendix A Specifications for VXI-MIO-64E-1
Analog Output
Output Characteristics
Number of channels .......................... 2 voltage
Resolution ......................................... 12 bits, 1 in 4,096
Max update rate
FIFO mode waveform generation
Internally timed ...................1 MS/s per channel
All other cases ............................950 kS/s per channel
Type of DAC..................................... Double buffered, multiplying
FIFO buffer size ............................... 2,048 samples
Data transfers .................................... DMA, interrupts,
programmed I/O
Transfer Characteristics
Relative accuracy (INL)
After calibration..........................±0.3 LSB typ, ±0.5 LSB max
Before calibration .......................±4 LSB max
DNL
After calibration..........................±0.3 LSB typ, ±1.0 LSB max
Before calibration .......................±3 LSB max
Monotonicity..................................... 12 bits, guaranteed after
calibration
Offset error
After calibration..........................±1.0 mV max
Before calibration .......................±200 mV max
Gain error (relative to internal reference)
After calibration..........................±0.01% of output max
Before calibration .......................±0.5% of output max
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Appendix A Specifications for VXI-MIO-64E-1
Gain error
(relative to external reference) ...........+0% to +0.5% of output max, not
adjustable
Voltage Output
Ranges ...............................................±5 V, 0 to 10 V, ±EXTREF,
0 to EXTREF
(software-selectable)
Output coupling .................................DC
Output impedance ..............................0.1 Ω max
Current drive......................................±5 mA max
Protection...........................................Short-circuit to ground
Power-on state ...................................0 V
External reference input
Range ......................................... ±11 V
Overvoltage protection ............... ±25 V powered on, ±15 V
powered off
Input impedance ......................... 10 kΩ
Bandwidth (-3 dB)...................... 1 MHz
Dynamic Characteristics
Settling time for full-scale step ..........3 µs to ±0.5 LSB accuracy
Slew rate............................................20 V/µs
Noise .................................................200 µVrms, DC to 1 MHz
Glitch energy (at midscale transition)
Magnitude
Reglitching disabled............. ±70 mV
Reglitching enabled ............. ±40 mV
Duration ..................................... 1.5 µs
Stability
Offset temperature coefficient............±50 µV/°C
Gain temperature coefficient
Internal reference........................ ±25 ppm/°C
External reference....................... ±25 ppm/°C
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Appendix A Specifications for VXI-MIO-64E-1
Onboard calibration reference
Level...........................................5.000 V (±0.5 mV) (actual value
stored in EEPROM)
Temperature coefficient ..............±0.6 ppm/°C max
Long-term stability .....................±6 ppm/
1,000 h
Digital I/O
Number of channels .......................... 8 input/output
Compatibility .................................... TTL/CMOS
Digital logic levels ............
Level
Min
0 V
2 V
—
Max
0.8 V
5 V
Input low voltage
Input high voltage
Input low current
-320 µA
(V = 0 V)
in
Input high current
(V = 5 V)
in
—
10 µA
Output low
voltage
—
0.4 V
—
(I = 24 mA)
OL
Output high
voltage
4.35 V
(I = 13 mA)
OH
Power-on state................................... Input (High-Z)
Data transfers .................................... Programmed I/O
Timing I/O
Number of channels .......................... 2 up/down counter/timers,
1 frequency scaler
Resolution
Counter/timers ............................24 bits
Frequency scalers........................4 bits
Compatibility .................................... TTL/CMOS
Base clocks available
Counter/timers ............................20 MHz, 100 kHz
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Appendix A Specifications for VXI-MIO-64E-1
Frequency scalers ....................... 10 MHz, 100 kHz
Base clock accuracy...........................±0.01%
Max source frequency........................20 MHz
Min source pulse duration..................10 ns in edge-detect mode
Min gate pulse duration......................10 ns in edge-detect mode
Data transfers.....................................DMA, interrupts, programmed
I/O
Triggers
Analog Trigger
Source................................................ACH<0..63>, PFI0/TRIG1
Level..................................................± full-scale, internal; ±10 V,
external
Slope..................................................Positive or negative (software
selectable)
Resolution..........................................8 bits, 1 in 256
Hysteresis ..........................................Programmable
Bandwidth (-3 dB) .............................1.5 MHz internal,
7 MHz external
External input (PFI0/TRIG1)
Impedance .................................. 10 kΩ
Coupling .................................... DC
Protection ................................... -0.5 to 5.5 V when configured as
a digital signal;
±35 V when configured as an
analog trigger signal or disabled;
±35 V powered off
Digital Trigger
Compatibility.....................................TTL
Response............................................Rising or falling edge
Pulse width ........................................10 ns min
VXIbus Trigger
Trigger lines.......................................Supports 5 TTL and 2 ECL
trigger lines
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Appendix A Specifications for VXI-MIO-64E-1
Power Requirement
+5 VDC............................................. 1.80 A typ; 2.16 A max*
(*Not including current used by
accessories.)
-5.2 VDC........................................... 0.15 A typ; 0.18 A max
-2 VDC.............................................. 0.04 A typ; 0.06 A max
+24 VDC........................................... 0.09 A typ; 0.10 A max
-24 VDC............................................ 0.09 A typ; 0.10 A max
Power available at I/O connector....... +4.65 VDC to +5.25 VDC
at 1 A
Physical
Dimensions ...................................... VXI C-size single slot
I/O connector .................................... 96-pin DIN
Environment
Operating temperature....................... 0° to 55° C
Storage temperature........................... -20° to 70° C
Relative humidity.............................. 5% to 90% noncondensing
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Appendix A Specifications for VXI-MIO-64XE-10
VXI-MIO-64XE-10
Analog Input
Input Characteristics
Number of channels ...........................64 single-ended or 32
differential (software selectable)
Type of ADC .....................................Successive approximation
Resolution..........................................16 bits, 1 in 65,536
Maximum sampling rate.....................100 kS/s guaranteed
Input signal ranges ................
Module Gain
(Software
Module Range
(Software Selectable)
Selectable)
Bipolar
Unipolar
1
2
±10.0 V
±5.0 V
±2.0 V
±1.0 V
±0.5 V
±0.2 V
±0.1 V
0 to 10 V
0 to 5 V
5
0 to 2 V
10
20
50
100
0 to 1 V
0 to 0.5 V
0 to 0.2 V
0 to 0.1 V
Input coupling....................................DC
Maximum working voltage ................Each input should remain within
±11 V of ground
Overvoltage protection.......................±25 V powered on, ±15 V
powered off
Inputs protected .......................... ACH<0..63>, AISENSE,
AISENSE2
FIFO buffer size.................................512 S
Data transfers.....................................DMA, interrupts, programmed
I/O
Configuration memory size................512 words
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Appendix A Specifications for VXI-MIO-64XE-10
Transfer Characteristics
Relative accuracy .............................. ±0.75 LSB typ, ±1 LSB max
DNL .................................................. ±0.5 LSB typ, ±1 LSB max
No missing codes .............................. 16 bits, guaranteed
Offset error
Pregain error after calibration .....±3 µV max
Pregain error before calibration...±2.2 mV max
Postgain error after calibration....±76 µV max
Postgain error before calibration .±102 mV max
Gain error (relative to calibration reference)
After calibration (gain = 1) .........±30.5 ppm of reading max
Before calibration .......................±2,150 ppm of reading max
With gain error adjusted to 0 at gain = 1
Gain ≠ 1......................................±200 ppm of reading
Amplifier Characteristics
Input impedance
Normal, powered on....................100 GΩ in parallel with 100 pF
Powered off ................................1 kΩ min
Overload .....................................1 kΩ min
Input bias current .............................. ±1 nA
Input offset current............................ ±2 nA
CMRR, DC to 60 Hz
Gain = 1......................................92 dB
Gain = 2......................................97 dB
Gain = 5......................................101 dB
Gain = 10....................................104 dB
Gain = 20....................................105 dB
Gain = 50....................................105 dB
Gain = 100 ..................................105 dB
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Appendix A Specifications for VXI-MIO-64XE-10
Dynamic Characteristics
Bandwidth
All gains ..................................... 255 kHz
Settling time for full-scale step, all gains and ranges
To ±0.5 LSB............................... 50 µs typ
To ±1 LSB.................................. 25 µs typ
To ±6 LSB.................................. 10 µs typ
System noise (including quantization noise)
Gain = 1, 2, 5, 10........................ 0.6 LSB rms bipolar,
0.8 LSB rms unipolar
Gain = 20.................................... 0.7 LSB rms bipolar,
1.1 LSB rms unipolar
Gain = 50.................................... 1.1 LSB rms bipolar,
2.0 LSB rms unipolar
Gain = 100.................................. 2.0 LSB rms bipolar,
3.8 LSB rms unipolar
Dynamic range...................................91.7 dB, full-scale input with
gain 1 to 10
Crosstalk............................................-70 dB max, DC to 100 kHz
Stability
Recommended warm-up time.............15 min.
Offset temperature coefficient
Pregain ....................................... ±5 µV/°C
Postgain...................................... ±120 µV/°C
Gain temperature coefficient..............±7 ppm/°C
Onboard calibration reference
Level..................................................5.000 V (±0.5 mV) (actual value
stored in EEPROM)
Temperature coefficient .....................±0.6 ppm/°C max
Long-term stability ............................±6 ppm/
1,000 h
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Appendix A Specifications for VXI-MIO-64XE-10
Analog Output
Output Characteristics
Number of channels .......................... 2 voltage
Resolution ......................................... 16 bits, 1 in 65,536
Max update rate................................. 100 kS/s
Type of DAC .................................... Double-buffered
FIFO buffer size................................ 2,048 samples
Data transfers .................................... DMA, interrupts, programmed
I/O
Transfer Characteristics
Relative accuracy (INL) .................... ±0.5 LSB typ, ±1 LSB max
DNL .................................................. ±1 LSB max
Monotonicity..................................... 16 bits, guaranteed
Offset error
After calibration..........................305 µV max
Before calibration .......................20 mV max
Gain error (relative to internal reference)
After calibration..........................±30.5 ppm max
Before calibration .......................±2,000 ppm max
Voltage Output
Range ................................................ ±10 V, 0 to 10 V
(software selectable)
Output coupling................................. DC
Output impedance ............................. 0.1 Ω max
Current drive ..................................... ±5 mA
Protection ......................................... Short-circuit to ground
Power-on state................................... 0 V (± 20 mV)
Dynamic Characteristics
Settling time for full-scale step.......... 10 µs to ±1 LSB accuracy
Slew rate ........................................... 5 V/µs
Noise................................................. 60 µVrms, DC to 1 MHz
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Appendix A Specifications for VXI-MIO-64XE-10
Stability
Offset temperature coefficient............±50 µV/°C
Gain temperature coefficient..............±7.5 ppm/°C
Onboard calibration reference
Level .......................................... 5.000 V (±0.5 mV) (actual value
stored in EEPROM)
Temperature coefficient.............. ±0.6 ppm/°C max
Long-term stability ..................... ±6 ppm/
1,000 h
Digital I/O
Number of channels ...........................8 input/output
Compatibility.....................................TTL/CMOS
Digital logic levels............
Level
Min
0 V
2 V
—
Max
0.8 V
5 V
Input low voltage
Input high voltage
Input low current
Input high current
-320 µA
10 µA
—
Output low
voltage
(I = 24 mA)
OL
—
0.4 V
Output high
voltage
(I
= 13 mA)
4.35 V
—
OH
Power-on state ...................................Input (High-Z)
Data transfers.....................................Programmed I/O
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Appendix A Specifications for VXI-MIO-64XE-10
Timing I/O
Number of channels .......................... 2 up/down counter/timers,
1 frequency scaler
Resolution
Counter/timers ............................24 bits
Frequency scaler .........................4 bits
Compatibility .................................... TTL/CMOS
Base clocks available
Counter/timers ............................20 MHz, 100 kHz
Frequency scaler .........................10 MHz, 100 kHz
Base clock accuracy .......................... ±0.01%
Max source frequency ....................... 20 MHz
Min source pulse duration ................ 10 ns, edge-detect mode
Min gate pulse duration .................... 10 ns, edge-detect mode
Data transfers .................................... DMA, interrupts,
programmed I/O
Triggers
Analog Trigger
Source ............................................... ACH<0..63>, PFI0/TRIG1
Level ................................................. ± Fullscale, internal;
±10 V, external
Slope ................................................. Positive or negative
(software selectable)
Resolution ......................................... 12 bits, 1 in 4,096
Hysteresis.......................................... Programmable
Bandwidth (-3 dB)............................. 255 kHz internal,
4 MHz external
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Appendix A Specifications for VXI-MIO-64XE-10
External input (PFI0/TRIG1)
Impedance .................................. 10 kΩ
Coupling..................................... DC
Protection ................................... -0.5 to 5.5 V when configured as
a digital signal;
±35 V when configured as an
analog trigger signal or disabled;
±35 V powered off
Accuracy............................................±1% of fullscale range
Digital Trigger
Compatibility.....................................TTL
Response............................................Rising or falling edge
Pulse width ........................................10 ns min
VXIbus Trigger
Trigger lines.......................................Supports 5 TTL and 2 ECL
trigger lines
Power Requirement
+5 VDC .............................................2.82 A typ; 3.38 A max*
(*Not including current used by
accessories.)
-5.2 VDC ...........................................0.15 A typ; 0.18 A max
-2 VDC ..............................................0.04 A typ; 0.06 A max
Power available at I/O connector .......+4.65 VDC to +5.25 VDC
at 1 A
Physical
Dimensions .......................................VXI C-size single slot
I/O connector .....................................96-pin DIN
Environment
Operating temperature........................0 to 55° C
Storage temperature ...........................-20 to 70° C
Relative humidity...............................5% to 90% noncondensing
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Appendix
Optional Cable Connector
Descriptions
B
This appendix describes the connectors on the optional cables for the
VXI-MIO Series modules.
Figure B-1 shows the pin assignments for the 68-pin MIO connector.
This connector is one of the two 68-pin connectors available when you
use the SH966868 cable assembly with the VXI-MIO-64E-1 or
VXI-MIO-64XE-10.
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Appendix B Optional Cable Connector Descriptions
34 68
ACH1 33 67
ACH8
ACH0
AIGND
ACH9
32 66
31 65
30 64
29 63
28 62
AIGND
ACH10
ACH3
ACH2
AIGND
ACH11
AISENSE
ACH12
ACH5
AIGND
ACH4
AIGND 27 61
ACH13 26 60
ACH6
AIGND 24 58
25 59
AIGND
ACH14
ACH7
ACH15
23 57
22 56
21 55
AIGND
AOGND
AOGND
DGND
DIO0
DAC0OUT
DAC1OUT
EXTREF* 20 54
19 53
18 52
17 51
16 50
15 49
DIO4
DGND
DIO1
DIO5
DIO6
DGND
DIO2
DGND
+5 V 14 48
DGND 13 47
DGND 12 46
DIO7
DIO3
SCANCLK
PFI0/TRIG1
11 45
10 44
EXTSTROBE*
DGND
PFI1/TRIG2
DGND
9
8
7
6
5
4
3
2
1
43
42
41
40
39
38
37
36
35
PFI2/CONVERT*
PFI3/GPCTR1_SOURCE
PFI4/GPCTR1_GATE
GPCTR1_OUT
DGND
+5 V
DGND
PFI5/UPDATE*
PFI6/WFTRIG
DGND
PFI7/STARTSCAN
PFI8/GPCTR0_SOURCE
DGND
PFI9/GPCTR0_GATE
GPCTR0_OUT
FREQ_OUT
DGND
* Not connected on the VXI-MIO-64XE-10
Figure B-1. 68-Pin MIO Connector Pin Assignments
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Appendix B Optional Cable Connector Descriptions
Figure B-2 shows the pin assignments for the 68-pin extended analog
input connector. This is the other 68-pin connector available when you
use the SH966868 cable assembly with the VXI-MIO-64E-1 or
VXI-MIO-64XE-10.
34 68
ACH 17 33 67
ACH 24
ACH 16
ACH 25
ACH 26
ACH 19
ACH 28
ACH 29
ACH 22
ACH 31
ACH 40
ACH 33
ACH 42
ACH 43
AISENSE2
ACH 36
ACH 45
ACH 46
ACH 39
32 66
31 65
30 64
29 63
28 62
ACH 18
ACH 27
ACH 20
ACH 21
ACH 30
ACH 23 27 61
ACH 32 26 60
ACH 41
ACH 34 24 58
25 59
ACH 35
23 57
22 56
21 55
AIGND
ACH 44
ACH 37 20 54
19 53
18 52
17 51
16 50
15 49
ACH 38
ACH 47
ACH 48
ACH 49
ACH 58
ACH 56
ACH 57
ACH 50
ACH 51 14 48
ACH 52 13 47
ACH 61 12 46
ACH 59
ACH 60
ACH 53
ACH 62
ACH 63
NC
ACH 54
ACH 55
NC
11 45
10 44
9
8
7
6
5
4
3
2
1
43
42
41
40
39
38
37
36
35
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
Figure B-2. 68-Pin Extended Analog Input Connector Pin Assignments
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Appendix
C
Common Questions
This appendix contains a list of commonly asked questions and their
answers relating to usage and special features of your VXI-MIO Series
module.
General Information
1. What is the DAQ-STC?
The DAQ-STC is the system timing control ASIC
(application-specific integrated circuit) designed by National
Instruments and is the backbone of the VXI-MIO Series modules.
The DAQ-STC contains seven 24-bit counters and three 16-bit
counters. The counters are divided into three groups:
•
•
•
Analog input—two 24-bit, two 16-bit counters
Analog output—three 24-bit, one 16-bit counters
General-purpose counter/timer functions—two 24-bit counters
The groups can be configured independently with timing
resolutions of 50 ns or 10 µs. With the DAQ-STC, you can
interconnect a wide variety of internal timing signals to other
internal blocks. The interconnection scheme is quite flexible and
completely software configurable. New capabilities such as
buffered pulse generation, equivalent time sampling, and
seamlessly changing the sampling rate are possible.
2. How fast is each VXI-MIO Series module?
The last numeral in the name of an VXI-MIO Series module
specifies the fastest sample period in microseconds for that
particular module. For example, the VXI-MIO-64E-1 has a 1 µs
sample period, which corresponds to a sampling rate of 1.25 MS/s.
These sampling rates are aggregate: one channel at 1.25 MS/s or
two channels at 500 kS/s per channel illustrates the relationship.
Notice, however, that some VXI-MIO Series modules have settling
times that vary with gain and accuracy. See Appendix A for exact
specifications.
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Appendix C Common Questions
3. What type of 5 V protection do the VXI-MIO Series modules
have?
The VXI-MIO Series modules have 5 V lines equipped with a
self-resetting 1 A fuse.
Installation and Configuration
4. What jumpers should I be aware of when configuring my
VXI-MIO Series module?
Refer to the Module Configuration section of Chapter 2,
Installation and Configuration, for this information.
5. Which National Instruments document should I read first to get
started using DAQ software?
The release notes document for your application or driver software
is always the best starting place.
6. What version of NI-DAQ must I have to program my
VXI-MIO Series module?
You must have NI-DAQ version 4.9.0 or higher for the
VXI-MIO-64E-1 or VXI-MIO-64XE-10 modules.
7. What is the best way to test my module without having to program
the module?
The NI-DAQ Configuration Utility (formerly WDAQCONF) has a
Test menu with some excellent tools for doing simple functional
tests of the module, such as analog input and output, digital I/O,
and counter/timer tests. Also, the Test Configuration option will
verify that the logical address and interrupt settings for the module
are functioning properly.
Analog Input and Output
8. I’m using my module in differential analog input mode and I have
connected a differential input signal, but my readings are random
and drift rapidly. What’s wrong?
Check your ground reference connections. Your signal may be
referenced to a level that is considered floating with reference to
the module ground reference. Even if you are in differential mode,
the signal must still be referenced to the same ground level as the
module reference. There are various methods of achieving this
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Appendix C Common Questions
while maintaining a high common-mode rejection ratio (CMRR).
These methods are outlined in Chapter 4, Signal Connections.
9. Can I sample across a number of channels on a VXI-MIO Series
module while each channel is being sampled at a different rate?
NI-DAQ features a function called SCAN_Sequence_Setup,
which allows for multirate scanning of your analog input channels.
Refer to the NI-DAQ Function Reference Manual for PC
Compatibles for more details.
10. I’m using the DACs to generate a waveform, but I discovered with
a digital oscilloscope that there are glitches on the output signal. Is
this normal?
When it switches from one voltage to another, any DAC produces
glitches due to released charges. The largest glitches occur when
the most significant bit (MSB) of the D/A code switches. You can
build a lowpass deglitching filter to remove some of these glitches,
depending on the frequency and nature of your output signal. The
VXI-MIO-64E-1 module has built-in reglitchers, which can be
enabled through software, on its analog output channels. See the
Analog Output Reglitch Selection section in Chapter 3 for more
information about reglitching.
11. Can I synchronize a one-channel analog input data acquisition
with a one-channel analog output waveform generation on my
VXI-MIO Series module?
Yes. One way to accomplish this is to use the waveform generation
timing pulses to control the analog input data acquisition. To do
this, follow steps a through d below, in addition to the usual steps
for data acquisition and waveform generation configuration.
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a. Enable the PFI5 line for output, as follows:
If you are using NI-DAQ, call
Select_Signal(deviceNumber, ND_PFI_5,
ND_OUT_UPDATE, ND_HIGH_TO_LOW).
If you are using LabVIEW, invoke the Route Signal VI with
signal name set to PFI5 and signal source set to AO Update.
b. Set up data acquisition timing so that the timing signal for
A/D conversion comes from PFI5, as follows:
If you are using NI-DAQ, call
Select_Signal(deviceNumber, ND_IN_CONVERT,
ND_PFI_5, ND_HIGH_TO_LOW).
If you are using LabVIEW, invoke the AI Clock Config VI
with clock source code set to PFI pin, high to low, and clock
source string set to 5.
c. Initiate analog input data acquisition, which will start only
when the analog output waveform generation starts.
If you are using NI-DAQ, call DAQ_Startwith appropriate
parameters.
If you are using LabVIEW, invoke the AI Control VI with
control code set to 0 (start).
d. Initiate analog output waveform generation.
If you are using NI-DAQ, call WFM_Group_Controlwith
operation set to 1 (start).
If you are using LabVIEW, invoke the AO Control VI with
control code set to 0 (start).
Timing and Digital I/O
12. What types of triggering can be hardware implemented on my
VXI-MIO Series module?
Digital triggering is supported by hardware on every
VXI-MIO Series module. In addition, the VXI-MIO-64E-1 and
VXI-MIO-64XE-10 support analog triggering in hardware.
13. What added functionality does the DAQ-STC make possible in
contrast to the Am9513?
The DAQ-STC incorporates much more than just 10 Am9513-style
counters within one chip. In fact, the DAQ-STC has the complexity
of more than 24 chips. The DAQ-STC makes possible PFI lines,
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analog triggering, selectable logic level, and frequency shift
keying. The DAQ-STC also makes buffered operations possible,
such as direct up/down control, single or pulse train generation,
equivalent time sampling, buffered period, and buffered
semiperiod measurement.
14. I’m using one of the general-purpose counter/timers on my
VXI-MIO Series module, but I do not see the counter/timer output
on the I/O connector. What am I doing wrong?
If you are using the NI-DAQ language interface or
LabWindows/CVI, you must configure the output line to output the
signal to the I/O connector. Use the Select_Signalcall in
NI-DAQ to configure the output line. By default, all timing I/O
lines except EXTSTROBE* are tri-stated.
15. How does NI-DAQ treat bogus missed data transfer errors that
can arise during DMA-driven GPCTR buffered-input operations?
When doing buffered transfers using GPCTR function calls with
DMA, you can call GPCTR_Watchto indicate dataTransfer
errors. NI-DAQ takes a snapshot of transfers and counts how many
points have been transferred. If all the points have been transferred
and the first instance of this error occurs, NI-DAQ returns a
gpctrDataTransferWarning indicating that the error could be
bogus. If all the points have not been transferred, NI-DAQ returns
the genuine error. The error continues to be returned until the
acquisition completes. The error occurs because NI-DAQ disarms
the counter from generating any more requests in the interrupt
service routine. Due to interrupt latencies, it is possible that the
counter may have generated some spurious requests which the
DMA controller may not satisfy because it has already transferred
the required number of points.
16. What are the PFIs and how do I configure these lines?
PFIs are Programmable Function Inputs. These lines serve as
connections to virtually all internal timing signals.
If you are using the NI-DAQ language interface or
LabWindows/CVI, use the Select_Signalfunction to route
internal signals to the I/O connector, route external signals to
internal timing sources, or tie internal timing signals together.
If you are using NI-DAQ with LabVIEW and you want to connect
external signal sources to the PFI lines, you can use the AI Clock
Config, AI Trigger Config, AO Clock Config, AO Trigger and
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Gate Config, CTR Mode Config, and CTR Pulse Config advanced
level VIs to indicate which function the connected signal will
serve. Use the Route Signal VI to enable the PFI lines to output
internal signals.
Warning: If you enable a PFI line for output, do not connect any external signal
source to it; if you do, you can damage the module and the connected
equipment.
17. What are the power-on states of the PFI and DIO lines on the I/O
connector?
At system power-on and reset, both the PFI and DIO lines are set
to high impedance by the hardware. This means that the module
circuitry is not actively driving the output either high or low.
However, these lines may have pull-up or pull-down resistors
connected to them as shown in Table 4-1. These resistors weakly
pull the output to either a logic high or logic low state. For example,
DIO(0) will be in the high-impedance state after power on, and
Table 4-1 shows that there is a 50 kΩ pull-up resistor. This pull-up
resistor will set the DIO(0) pin to a logic high when the output is in
a high-impedance state.
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Appendix
D
Customer Communication
For your convenience, this appendix contains forms to help you gather the information necessary
to help us solve your technical problems and a form you can use to comment on the product
documentation. When you contact us, we need the information on the Technical Support Form
and the configuration form, if your manual contains one, about your system configuration to
answer your questions as quickly as possible.
National Instruments has technical assistance through electronic, fax, and telephone systems to
quickly provide the information you need. Our electronic services include a bulletin board
service, an FTP site, a FaxBack system, and e-mail support. If you have a hardware or software
problem, first try the electronic support systems. If the information available on these systems
does not answer your questions, we offer fax and telephone support through our technical support
centers, which are staffed by applications engineers.
Electronic Services
Bulletin Board Support
National Instruments has BBS and FTP sites dedicated for 24-hour support with a collection of
files and documents to answer most common customer questions. From these sites, you can also
download the latest instrument drivers, updates, and example programs. For recorded instructions
on how to use the bulletin board and FTP services and for BBS automated information, call
(512) 795-6990. You can access these services at:
United States: (512) 794-5422 or (800) 327-3077
Up to 14,400 baud, 8 data bits, 1 stop bit, no parity
United Kingdom: 01635 551422
Up to 9,600 baud, 8 data bits, 1 stop bit, no parity
France: 1 48 65 15 59
Up to 9,600 baud, 8 data bits, 1 stop bit, no parity
FTP Support
To access our FTP site, log on to our Internet host, ftp.natinst.com, as anonymous and use
and documents are located in the /supportdirectories.
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FaxBack Support
FaxBack is a 24-hour information retrieval system containing a library of documents on a wide
range of technical information. You can access FaxBack from a touch-tone telephone at
(512) 418-1111.
E-Mail Support (currently U.S. only)
You can submit technical support questions to the appropriate applications engineering team
through e-mail at the Internet addresses listed below. Remember to include your name, address,
and phone number so we can contact you with solutions and suggestions.
GPIB: [email protected]
DAQ: [email protected]
VXI: [email protected]
LabWindows: [email protected]
LabVIEW: [email protected]
HiQ: [email protected]
VISA: [email protected]
Lookout: [email protected]
Fax and Telephone Support
National Instruments has branch offices all over the world. Use the list below to find the technical
support number for your country. If there is no National Instruments office in your country,
contact the source from which you purchased your software to obtain support.
Telephone
Fax
Australia
Austria
03 9879 5166
03 9879 6277
0662 45 79 90 19
02 757 03 11
905 785 0086
514 694 4399
45 76 26 02
90 502 2930
01 48 14 24 14
089 714 60 35
2686 8505
03 5734816
02 41309215
03 5472 2977
02 596 7455
5 520 3282
0348 430673
32 84 86 00
2265887
91 640 0533
08 730 43 70
056 200 51 55
02 737 4644
01635 523154
0662 45 79 90 0
02 757 00 20
905 785 0085
514 694 8521
45 76 26 00
90 527 2321
01 48 14 24 24
089 741 31 30
2645 3186
Belgium
Canada (Ontario)
Canada (Quebec)
Denmark
Finland
France
Germany
Hong Kong
Israel
Italy
Japan
Korea
Mexico
Netherlands
Norway
Singapore
Spain
03 5734815
02 413091
03 5472 2970
02 596 7456
95 800 010 0793
0348 433466
32 84 84 00
2265886
91 640 0085
08 730 49 70
056 200 51 51
02 377 1200
01635 523545
Sweden
Switzerland
Taiwan
U.K.
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Technical Support Form
Photocopy this form and update it each time you make changes to your software or hardware, and
use the completed copy of this form as a reference for your current configuration. Completing
this form accurately before contacting National Instruments for technical support helps our
applications engineers answer your questions more efficiently.
If you are using any National Instruments hardware or software products related to this problem,
include the configuration forms from their user manuals. Include additional pages if necessary.
Name__________________________________________________________________________
Company_______________________________________________________________________
Address ________________________________________________________________________
_______________________________________________________________________________
Fax (___ )___________________ Phone (___ ) ________________________________________
Computer brand ________________ Model ________________ Processor __________________
Operating system (include version number)____________________________________________
Clock speed ______MHz RAM _____MB
Mouse ___yes ___no Other adapters installed _______________________________________
Hard disk capacity _____MB Brand ____________________________________________
Display adapter _________
Instruments used ________________________________________________________________
_______________________________________________________________________________
National Instruments hardware product model_________ Revision ________________________
Configuration ___________________________________________________________________
National Instruments software product____________________________ Version_____________
Configuration ___________________________________________________________________
The problem is: _________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
List any error messages: ___________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
The following steps reproduce the problem: ___________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
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VXI-MIO Series Hardware and Software
Configuration Form
Record the settings and revisions of your hardware and software on the line to the right of each
item. Complete a new copy of this form each time you revise your software or hardware
configuration, and use this form as a reference for your current configuration. Completing this
form accurately before contacting National Instruments for technical support helps our
applications engineers answer your questions more efficiently.
National Instruments Products
VXI-MIO Series Module ________________________________________________________
VXI-MIO Series Module Serial Number ____________________________________________
Interrupt Level of VXI-MIO Series Module __________________________________________
DMA Channels of VXI-MIO Series Module _________________________________________
Base I/O Address of VXI-MIO Series Module ________________________________________
Programming Choice (NI-DAQ, LabVIEW, LabWindows/CVI, or other) ___________________
Software Version ______________________________________________________________
Other Products
Computer Model ______________________________________________________________
Microprocessor _______________________________________________________________
Clock Frequency ______________________________________________________________
Type of Video Board Installed ___________________________________________________
Operating System (DOS or Windows) _____________________________________________
Operating System Version_______________________________________________________
Operating System Mode ________________________________________________________
Programming Language ________________________________________________________
Programming Language Version__________________________________________________
Other Boards in System_________________________________________________________
Base I/O Address of Other Boards ________________________________________________
DMA Channels of Other Boards __________________________________________________
Interrupt Level of Other Boards __________________________________________________
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Documentation Comment Form
National Instruments encourages you to comment on the documentation supplied with our
products. This information helps us provide quality products to meet your needs.
Title:
VXI-MIO Series User Manual
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Edition Date: August 1996
Part Number: 321246A-01
Please comment on the completeness, clarity, and organization of the manual.
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
If you find errors in the manual, please record the page numbers and describe the errors.
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
_______________________________________________________________________________
Thank you for your help.
Name _________________________________________________________________________
Title __________________________________________________________________________
Company_______________________________________________________________________
Address _______________________________________________________________________
_______________________________________________________________________________
Phone ( )_____________________________________________________________________
Mail to: Technical Publications
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Fax to: Technical Publications
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(512) 794-5678
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Glossary
Prefix
p-
Meaning
pico-
Value
-12
10
10
10
10
-9
-6
-3
3
n-
nano-
micro-
milli-
kilo-
µ-
m-
k-
10
10
10
6
9
M-
G-
mega-
giga-
Symbols
˚
degree
–
negative of, or minus
ohm
Ω
/
per
%
±
+
percent
plus or minus
positive of, or plus
square root of
+5 VDC source signal
+5V
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Glossary
A
A
amperes
A16 space
VXIbus address space equivalent to the VME 64 KB short address
space. In VXI, the upper 16 KB of A16 space is allocated for use
by VXI module’s configuration registers. This 16 KB region is
referred to as VXI configuration space.
A24 space
A32 space
VXIbus address space equivalent to the VME 16 MB standard
address space.
VXIbus address space equivalent to the VME 4 GB extended
address space.
AC
alternating current
analog input channel signal
analog-to-digital
ACH
A/D
ADC
A/D converter
address space
A set of 2n memory locations differentiated from other such sets
in VXI/VMEbus systems by six addressing lines known as
address modifiers. n is the number of address lines required to
uniquely specify a byte location in a given space. Valid numbers
for n are 16, 24, and 32. In VME/VXI, because there are six
address modifiers, there are 64 possible address spaces.
address window
A portion of address space that can be accessed from the
application program.
AIGATE
AIGND
analog input gate signal
analog input ground signal
analog input sense signal
AISENSE
AISENSE2
ANSI
analog input sense 2 signal
American National Standards Institute
analog output ground signal
AOGND
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Glossary
B
backplane
An assembly, typically a printed circuit board, with 96-pin
connectors and signal paths that bus the connector pins. VXIbus
systems will have two sets of bused connectors, called the J1 and
J2 backplanes, or have three sets of bused connectors, called the
J1, J2, and J3 backplane.
base address
A memory address that serves as the starting address for
programmable registers. All other addresses are located by adding
to the base address.
BCD
binary-coded decimal
BIOS
bipolar
basic input/output system or built-in operating system
A signal range that includes both positive and negative values (for
example, -5 to +5 V).
bit
One binary digit, either 0 or 1.
bus
The group of conductors that interconnect individual circuitry in
a computer. Typically, a bus is the expansion vehicle to which I/O
or other devices are connected.
byte
Eight related bits of data, an eight-bit binary number. Also used
to denote the amount of memory required to store one byte of
data.
C
C
Celsius
CalDAC
channel
calibration DAC
Pin or wire lead to which you apply or from which you read the
analog or digital signal. Analog signals can be single-ended or
differential. For digital signals, you group channels to form ports.
Ports usually consist of either four or eight digital channels.
clock
Hardware component that controls timing for reading from or
writing to groups.
CMOS
CMRR
complementary metal-oxide semiconductor
common-mode rejection ratio
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Glossary
command
Any communication, from a Commander to a Message-Based-
Servant, that consists of a write to the Servants Data Low register,
possibly preceded by a write to the Data High or Data High and
Data Extended registers.
commander
A message-based device that is also a bus master and can control
one or more servants.
component software
An application that contains one or more component objects that
can freely interact with other component software. Examples
include OLE-enabled applications such as Microsoft Visual Basic
and OLE Controls for virtual instrumentation in
ComponentWorks.
Configuration Registers
(1) A set of registers through which the system can identify a
module device type, model, manufacturer, address space, and
memory requirements. In order to support automatic system and
memory configuration, the VXIbus specification requires that all
VXIbus devices have a set of such registers. (2) The A16 registers
of a device that are required for the system configuration process.
CONVERT*
counter/timer
crosstalk
convert signal
A circuit that counts external pulses or clock pulses (timing).
An unwanted signal on one channel due to an input on a different
channel.
D
D/A
digital-to-analog
DAC
D/A converter
DAC0OUT
DAC1OUT
DAQ
analog channel 0 output signal
analog channel 1 output signal
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 and/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
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Glossary
default setting
A default parameter value recorded in the driver. In many cases,
the default input of a control is a certain value (often 0) that means
use the current default setting. For example, the default input for
a parameter may be do not change current setting, and the default
setting may be no AMUX-64T boards. If you do change the value
of such a parameter, the new value becomes the new setting. You
can set default settings for some parameters in the configuration
utility or by manually using switches located on the device.
device
(1) A plug-in data acquisition board, card, or pad that can contain
multiple channels and conversion devices. Plug-in boards,
PCMCIA cards, and devices such as the DAQPad-1200, which
connects to your computer parallel port, are all examples of DAQ
devices. (2) A component of a VXIbus system, normally one
VXIbus board. However, multiple-slot devices and multiple-
device modules can operate on a VXIbus system as a single
device. Some examples of devices are computers, multimeters,
multiplexers, oscillators, operator interfaces, and counters.
DGND
digital ground signal
differential mode
DIFF
differential input
An analog input consisting of two terminals, both of which are
isolated from computer ground, whose difference is measured.
DIO
digital input/output
dithering
DLL
The addition of Gaussian noise to an analog input signal.
Dynamic Link Library—A software module in Microsoft
Windows containing executable code and data that can be called
or used by Windows applications or by other DLLs. Functions and
data in a DLL are loaded and linked at run time when they are
referenced by a Windows application or other DLLs.
DMA
DNL
Direct Memory Access—A method by which data can be
transferred to/from computer memory from/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.
differential nonlinearity—A measure in LSB of the worst-case
deviation of code widths from their ideal value of 1 LSB.
DRAM
Dynamic RAM
drivers/driver software
Software that controls a specific hardware device such as a DAQ
board.
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Glossary
dual-access memory
Memory that can be sequentially, but not simultaneously,
accessed by more than one controller or processor. Also known as
shared memory.
dual-ported memory
Memory that can be simultaneously accessed by more than one
controller or processor.
dynamic configuration
A method of automatically assigning logical addresses to VXIbus
devices at system startup or other configuration times. Each slot
can contain one or more devices. Different devices within a slot
can share address decoding hardware.
dynamically configured
device
A device that has its logical address assigned by the Resource
Manager. A VXI device initially responds at Logical Address 255
when its MODID line is asserted. The Resource Manager
subsequently assigns it a new logical address, which the device
responds to until powered down.
dynamic range
The ratio of the largest signal level a circuit can handle to the
smallest signal level it can handle (usually taken to be the noise
level), normally expressed in dB.
E
ECL
Emitter-Coupled Logic
EEPROM
electrically erasable programmable read-only memory—ROM
that can be erased with an electrical signal and reprogrammed.
EISA
Extended Industry Standard Architecture
embedded controller
An intelligent CPU (controller) interface plugged directly into the
VXI backplane, giving it direct access to the VXIbus. It must have
all of its required VXI interface capabilities built in.
event
Signals or interrupts generated by a device to notify another
device of an asynchronous event. The contents of events are
device-dependent.
external controller
In this configuration, a plug-in interface board in a computer is
connected to the VXI mainframe via one or more VXIbus
extended controllers. The computer then exerts overall control
over VXIbus system operations.
external trigger
A voltage pulse from an external source that triggers an event
such as A/D conversion.
EXTREF
external reference signal
external strobe signal
EXTSTROBE
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Glossary
F
FIFO
first-in-first-out memory buffer—The first data stored is the first
data sent to the acceptor. FIFOs are often used on DAQ devices to
temporarily store incoming or outgoing data until that data can be
retrieved or output. For example, an analog input FIFO stores the
results of A/D conversions until the data can be retrieved into
system memory, a process that requires the servicing of interrupts
and often the programming of the DMA controller. This process
can take several milliseconds in some cases. During this time,
data accumulates in the FIFO for future retrieval. With a larger
FIFO, longer latencies can be tolerated. In the case of analog
output, a FIFO permits faster update rates, because the waveform
data can be stored on the FIFO ahead of time. This again reduces
the effect of latencies associated with getting the data from system
memory to the DAQ device.
floating signal sources
Signal sources with voltage signals that are not connected to an
absolute reference or system ground. Also called nonreferenced
signal sources. Some common example of floating signal sources
are batteries, transformers, or thermocouples.
FREQ_OUT
ft
frequency output signal
feet
function
A set of software instructions executed by a single line of code
that may have input and/or output parameters and returns a value
when executed.
G
gain
The factor by which a signal is amplified, sometimes expressed in
decibels.
gain accuracy
A measure of deviation of the gain of an amplifier from the ideal
gain.
GND
ground signal or bit
GPCTR0_GATE
GPCTR1_GATE
GPCTR0_OUT
GPCTR1_OUT
GPCTR0_SOURCE
general purpose counter 0 gate signal
general purpose counter 1 gate signal
general purpose counter 0 output signal
general purpose counter 1 output signal
general purpose counter 0 clock source signal
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Glossary
GPCTR1_SOURCE
group
general purpose counter 1 clock source signal
A collection of digital ports, combined to form a larger entity for
digital input and/or output. Groups can contain analog input,
analog output, digital input, digital output, or counter/timer
channels. A group can contain only one type of channel, however.
You use a task ID number to refer to a group after you create it.
You can define up to 16 groups at one time. To erase a group, you
pass an empty channel array and the group number to the group
configuration VI. You do not need to erase a group to change its
membership. If you reconfigure a group whose task is active,
LabVIEW clears the task and returns a warning. LabVIEW does
not restart the task after you reconfigure the group.
H
h
hour
hardware
The physical components of a computer system, such as the
circuit boards, plug-in boards, chassis, enclosures, peripherals,
cables, and so on.
hardware triggering
A form of triggering where you set the start time of an acquisition
and gather data at a known position in time relative to a trigger
signal.
hex
Hz
hexadecimal
hertz—A unit of frequency equal to one cycle per second.
I
IC
integrated circuit
inches
in.
INL
Integral Nonlinearity—A measure in LSB of the worst-case
deviation from the ideal A/D or D/A transfer characteristic of the
analog I/O circuitry.
input range
The difference between the maximum and minimum voltages an
analog input channel can measure at a gain of 1. The input range
is a scalar value, not a pair of numbers. By itself the input range
does not uniquely determine the upper and lower voltage limits.
An input range of 10 V could mean an upper limit of +10 V and a
lower of 0 V or an upper limit of +5 V and a lower limit of -5 V.
The combination of input range, polarity, and gain determines the
input limits of an analog input channel. For some boards, jumpers
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set the input range and polarity, while you can program them for
other boards. Most boards have programmable gains.
instrument driver
interrupt
A set of high-level software functions that controls a specific VXI
or RS-232 programmable instrument or a specific plug-in DAQ
board.
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.
interval scanning
Scanning method where there is a longer interval between scans
than there is between individual channels comprising a scan.
I/O
input/output—The transfer of data to/from a computer system
involving communications channels, operator interface devices,
and/or data acquisition and control interfaces.
I
I
current, output high
OH
OL
current, output low
ISA
Industry Standard Architecture
K
KB
kS
kilobytes—1,024 bytes when referring to memory
1,000 samples
L
LabVIEW
LASTCHAN
LED
Laboratory Virtual Instrument Engineering Workbench
last channel (bit)
light-emitting diode
logical address
An 8-bit number that uniquely identifies each VXIbus device in a
system. It defines the A16 register addresses of a device, and
indicates Commander and Servant relationships.
LSB
least significant bit
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M
m
meters
mainframe
The chassis of a VXIbus system that mechanically contains VXI
modules inserted into the backplane, ensuring that connectors fit
properly and that adjacent modules do not contact each other. It
also provides cooling airflow, and ensures that modules do not
disengage from the backplane due to vibration or shock.
MB
megabytes of memory
memory device
MIO
A memory storage device that has configuration registers.
multifunction I/O
MITE
A National Instruments custom ASIC. A sophisticated dual-
channel DMA controller that incorporates the Synchronous MXI
and VME64 protocols to achieve high-performance block transfer
rates.
module
Typically a board assembly and its associated mechanical parts,
front panel, optional shields, and so on. A module contains
everything required to occupy one or more slots in a mainframe.
MSB
most significant bit
multitasking
A property of an operating system in which several processes can
be run simultaneously.
mux
multiplexer—A switching device with multiple inputs that
sequentially connects each of its inputs to its output, typically at
high speeds, in order to measure several signals with a single
analog input channel.
N
NC
Normally closed, or not connected
NI-DAQ
node
National Instruments driver software for DAQ hardware
Execution elements of a block diagram consisting of functions,
structures, and subVIs
noise
An undesirable electrical signal—Noise comes from external
sources such as the AC power line, motors, generators,
transformers, fluorescent lights, soldering irons, CRT displays,
computers, electrical storms, welders, radio transmitters, and
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internal sources such as semiconductors, resistors, and capacitors.
Noise corrupts signals you are trying to send or receive.
NRSE
nonreferenced single-ended mode—All measurements are made
with respect to a common (NRSE) measurement system
reference, but the voltage at this reference can vary with respect
to the measurement system ground.
O
OLE
Object Linking and Embedding—A set of system services that
provides a means for applications to interact and interoperate.
Based on the underlying Component Object Model, OLE is
object-enabling system software. Through OLE Automation, an
application can dynamically identify and use the services of other
applications, to build powerful solutions using packaged
software. OLE also makes it possible to create compound
documents consisting of multiple sources of information from
different applications.
onboard channels
operating system
Channels provided by the plug-in data acquisition board.
Base-level software that controls a computer, runs programs,
interacts with users, and communicates with installed hardware or
peripheral devices.
optical isolation
The technique of using an optoelectric transmitter and receiver to
transfer data without electrical continuity, to eliminate high-
potential differences and transients.
OUT
output
output limits
The upper and lower voltage or current outputs for an analog
output channel. The output limits determine the polarity and
voltage reference settings for a board.
output settling time
The amount of time required for the analog output voltage to
reach its final value within specified limits.
P
PC
personal computer
PFI
Programmable Function Input
Programmable Gain Instrumentation Amplifier
PGIA
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plug and play devices
port
Devices that do not require dip switches or jumpers to configure
resources on the devices—also called switchless devices.
(1) A communications connection on a computer or a remote
controller. (2) A digital port, consisting of four or eight lines of
digital input and/or output.
ppm
parts per million
pretriggering
The technique used on a DAQ board to keep a continuous buffer
filled with data, so that when the trigger conditions are met, the
sample includes the data leading up to the trigger condition.
Q
quantization error
The inherent uncertainty in digitizing an analog value due to the
finite resolution of the conversion process.
R
RAM
random access memory
referenced signal sources
Signal sources with voltage signals that are referenced to a system
ground, such as the earth or a building ground. Also called
grounded signal sources.
relative accuracy
A measure in LSB of the accuracy of an ADC. It includes all non-
linearity and quantization errors. It does not include offset and
gain errors of the circuitry feeding the ADC.
RESMAN
The name of the National Instruments Resource Manager in
NI-VXI bus interface software. See Resource Manager.
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.
Resource Manager
responses
A message-based Commander, located at logical address 0, which
provides configuration management services such as address map
configuration, Commander and Servant mappings, and self-test
and diagnostics management
Signals or interrupts generated by a device to notify another
device of an asynchronous event. Responses contain the
information in the Response register of a sender.
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rms
root mean square
RSE
referenced single-ended mode—All measurements are made with
respect to a common reference measurement system or a ground.
Also called a grounded measurement system.
RTD
resistive temperature detector—A metallic probe that measures
temperature based upon its coefficient of resistivity.
RTSI Bus
Real-Time System Integration Bus—The National Instruments
timing bus that connects DAQ boards directly for precise
synchronization of functions. For the VXI-MIO Series modules,
the RTSI bus trigger lines are implemented using VXIbus trigger
lines.
S
s
seconds
sample
S
scan
One or more analog or digital input samples. Typically, the
number of input samples in a scan is equal to the number of
channels in the input group. For example, one pulse from the scan
clock produces one scan which acquires one new sample from
every analog input channel in the group.
scan clock
The clock controlling the time interval between scans. On boards
with interval scanning support, this clock gates the channel clock
on and off. On boards with simultaneous sampling, this clock
clocks the track-and-hold circuitry.
SCANCLK
scan rate
scan clock signal
The number of scans per second.
scan width
The number of channels in the channel list or number of ports in
the port list you use to configure an analog or digital input group.
SCXI
Signal Conditioning eXtensions for Instrumentation—The
National Instruments product line for conditioning low-level
signals within an external chassis near sensors so only high-level
signals are sent to DAQ boards in the noisy PC environment.
SE
single-ended inputs—A term used to describe an analog input that
is measured with respect to a common ground.
settling time
The amount of time required for a voltage to reach its final value
within specified limits.
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signal
Any communication between message-based devices consisting
of a write to a Signal register.
SIMM
Single In-line Memory Module
SI counter clock signal
SISOURCE
slot
A position where a module can be inserted into a VXIbus
backplane. Each slot provides the 96-pin J connectors to interface
with the board P connectors. A slot can have one, two, or three
connectors.
S/s
Samples per Second—Used to express the rate at which a DAQ
board samples an analog signal.
STARTSCAN
start scan signal
statically configured device
A device whose logical address cannot be set through software;
that is, it is not dynamically configurable.
system
A system consists of one or more mainframes that are connected,
all sharing a common Resource Manager. Each device in a system
has a unique logical address.
system RAM
RAM installed on a personal computer and used by the operating
system, as contrasted with onboard RAM.
T
TC
terminal count—The highest value of a counter.
THD
total harmonic distortion—The ratio of the total rms signal due to
harmonic distortion to the overall rms signal, in dB or percent.
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.
TRIG
trigger
TTL
trigger signal
Any event that causes or starts some form of data capture.
transistor-transistor logic
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U
UI
update interval
UISOURCE
unipolar
update interval counter clock signal
Unipolar input means that the input voltage range is between 0
and V , where V is a positive reference voltage.
ref
ref
update
The output equivalent of a scan. One or more analog or digital
output samples. Typically, the number of output samples in an
update is equal to the number of channels in the output group. For
example, one pulse from the update clock produces one update
which sends one new sample to every analog output channel in the
group.
UPDATE
update signal
update rate
The number of output updates per second.
V
V
volts
VDC
VI
volts direct current
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.
VISA
A new driver software architecture developed by National
Instruments to unify instrumentation software (GPIB, DAQ, and
VXI). It has been accepted as a standard for VXI by the
VXIplug&play Systems Alliance.
V
V
V
V
V
V
volts, input high
volts, input low
volts in
IH
IL
in
volts, output high
volts, output low
reference voltage
OH
OL
ref
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VXIbus
VMEbus eXtensions for Instrumentation
VXIbus trigger lines
These are the eight TTL and two ECL lines on the VXIbus
backplane which are used for intermodule communication.
Typical applications are triggering and clocking measurements.
VXIplug&play Systems
Alliance
A group of VXI developers dedicated to making VXI devices as
easy to use as possible, primarily by simplifying software
development.
W
waveform
WFTRIG
wire
Multiple voltage readings taken at a specific sampling rate
waveform generation trigger signal
Data path between nodes.
word serial
The simplest required communication protocol used by message-
based devices in the VXIbus system. It uses the A16
communication registers to transfer data with a simple polling
handshake method.
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Index
analog input, 3-3 to 3-9
Numbers
common questions about, C-2 to C-4
considerations for selecting input
ranges, 3-6
dither, 3-7 to 3-8
input modes, 3-3 to 3-4
input polarity and range, 3-4 to 3-6
VXI-MIO-64E-1, 3-4 to 3-5
VXI-MIO-64XE-10, 3-5 to 3-6
multichannel scanning considerations,
3-8 to 3-9
+5 V signal
description, 4-3
power connections, 4-23
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
A
ACH<0..15> signal (table), 4-3
ACH<0..63> signal
signal connections, 4-9 to 4-20
analog input specifications
VXI-MIO-64E-1
analog input connections, 4-9
VXI-MIO-64XE-10 (table), 4-8
ACH<16..63> signal (table), 4-3
address, logical. See VXIbus logical address.
AIGATE signal, 4-33 to 4-34
AIGND signal
amplifier characteristics, A-3
dynamic characteristics, A-4
input characteristics, A-1 to A-2
stability, A-4
analog input connections, 4-9, 4-10
description (table), 4-3
transfer characteristics, A-3
VXI-MIO-64XE-10
differential connections for floating
signal sources, 4-16 to 4-17
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
AISENSE signal
amplifier characteristics, A-11
dynamic characteristics, A-12
input characteristics, A-10
stability, A-12
transfer characteristics, A-11
analog output, 3-10 to 3-11
common questions about, C-2 to C-4
output polarity selection, 3-10 to 3-11
reference selection, 3-10
reglitch selection, 3-11
signal connections, 4-20 to 4-21
analog output specifications
VXI-MIO-64E-1
analog input connections, 4-9, 4-10
description (table), 4-3
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
AISENSE2 signal
analog input connections, 4-9, 4-10
description (table), 4-3
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
amplifier characteristics
dynamic characteristics, A-6
output characteristics, A-5
stability, A-6 to A-7
VXI-MIO-64E-1, A-3
VXI-MIO-64XE-10, A-11
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transfer characteristics, A-5 to A-6
voltage output, A-6
VXI-MIO-64XE-10
C
cables. See also I/O connectors.
field wiring considerations, 4-45
optional cable connectors
68-pin extended analog input
connector pin assignments (figure),
B-3
dynamic characteristics, A-13
output characteristics, A-13
stability, A-14
transfer characteristics, A-13
voltage output, A-13
68-pin MIO connector pin
assignments (figure), B-2
optional equipment, 1-6
analog trigger, 3-11 to 3-14
above-high-level analog triggering mode
(figure), 3-13
calibration, 5-1 to 5-3
below-low-level analog triggering mode
(figure), 3-12
block diagram, 3-12
high-hysteresis analog triggering mode
(figure), 3-13
inside-region analog triggering mode
(figure), 3-13
low-hysteresis analog triggering mode
(figure), 3-14
specifications
adjusting for gain error, 5-3
external calibration, 5-2 to 5-3
loading calibration constants, 5-1 to 5-2
self-calibration, 5-2
charge injection, 3-9
commonly asked questions. See questions
about VXI-MIO series.
common-mode signal rejection, 4-20
ComponentWorks software, 1-2
configuration. See also input configurations.
block diagrams
VXI-MIO-64E-1, A-8
VXI-MIO-64XE-10, A-15 to A-16
AOGND signal
VXI-MIO-64E-1 parts locator
diagram, 2-3
VXI-MIO-64XE-10 parts locator
diagram, 2-4
analog output connections, 4-20 to 4-21
description (table), 4-3
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
common questions about, C-2
loading USER/FACTORY configuration,
2-7 to 2-8
B
protecting/changing FACTORY
configuration, 2-8
SIMM size, 2-5 to 2-6
bipolar input, mixing with unipolar channels
(note), 3-5
accessing SIMM sockets, 2-6
DRAM configuration (table),
2-6 to 2-7
bipolar output, 3-10 to 3-11
block diagrams
VXI-MIO series, 3-2
VXIbus logical address, 2-1 to 2-2
connectors. See I/O connectors.
CONVERT* signal
VXI-MIO-64E-1 parts locator
diagram, 2-3
VXI-MIO-64XE-10 parts locator
diagram, 2-4
signal routing, 3-15
timing connections, 4-32 to 4-33
input timing (figure), 4-32
output timing (figure), 4-33
customer communication, xiv, D-1 to D-2
board configuration. See configuration.
bulletin board support, D-1
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grounded signal sources (NRSE),
4-19 to 4-20
when to use, 4-14
digital I/O
D
DAC0OUT signal
analog output connections, 4-20 to 4-21
description (table), 4-3
common questions about, C-4 to C-6
operation, 3-14
signal connections, 4-22 to 4-23
specifications
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
DAC1OUT signal
analog output connections, 4-20 to 4-21
description (table), 4-3
VXI-MIO-64E-1, A-7
VXI-MIO-64XE-10, A-14
digital trigger specifications
VXI-MIO-64E-1, A-8
VXI-MIO-64XE-10, A-16
DIO<0..7> signal
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
DAQ-STC, C-1
data acquisition timing connections,
4-25 to 4-34
description (table), 4-3
AIGATE signal, 4-33 to 4-34
CONVERT* signal, 4-32 to 4-33
EXTSTROBE* signal, 4-26 to 4-27
posttriggered acquisition (figure), 4-25
pretriggered acquisition (figure), 4-26
SCANCLK signal, 4-26
digital I/O connections, 4-22 to 4-23
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
dither
enabling, 3-7 to 3-8
signal acquisition effects (figure), 3-8
documentation
conventions used in manual, xii
National Instruments documentation, xiii
organization of manual, xi-xii
related documentation, xiv
DRAM configuration (table), 2-6 to 2-7
dynamic characteristics
analog input
SISOURCE signal, 4-34
STARTSCAN signal, 4-30 to 4-31
TRIG1 signal, 4-27 to 4-28
TRIG2 signal, 4-28 to 4-29
DGND signal
description (table), 4-3
digital I/O connections, 4-22
power connections, 4-23
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
DIFF (differential) input mode
definition (table), 3-3
VXI-MIO-64E-1, A-4
VXI-MIO-64XE-10, A-12
analog output
VXI-MIO-64E-1, A-6
VXI-MIO-64XE-10, A-13
description, 4-14
ground-referenced signal sources, 4-15
illustration, 4-15
E
nonreferenced or floating signal sources,
4-16 to 4-17
illustration, 4-16
recommended configuration
(figure), 4-13
EEPROM
loading USER/FACTORY configuration,
2-7 to 2-8
protecting/changing factory
configuration, 2-8
storage of calibration constants, 5-1
single-ended connections, 4-18
floating signal sources (RSE), 4-19
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Index
e-mail support, D-2
environment specifications
VXI-MIO-64E-1, A-9
G
general-purpose timing signal connections,
4-38 to 4-44
VXI-MIO-64XE-10, A-16
environmental noise, avoiding, 4-45
equipment, optional, 1-5
EXTREF signal
FREQ_OUT signal, 4-44
GPCTR0_GATE signal, 4-39 to 4-40
GPCTR0_OUT signal, 4-40
GPCTR0_SOURCE signal, 4-38 to 4-39
GPCTR0_UP_DOWN signal, 4-40
GPCTR1_GATE signal, 4-41 to 4-42
GPCTR1_OUT signal, 4-42 to 4-43
GPCTR1_SOURCE signal, 4-41
GPCTR1_UP_DOWN signal,
4-43 to 4-44
analog output connections, 4-20 to 4-21
analog output reference selection, 3-10
description (table), 4-3
VXI-MIO-64E-1 (table), 4-6
EXTSTROBE* signal
description (table), 4-4
timing connections, 4-26 to 4-27
illustration, 4-27
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
GPCTR0_GATE signal, 4-39 to 4-40
GPCTR0_OUT signal
description (table), 4-5
VXI-MIO-64E-1 (table), 4-7
VXI-MIO-64XE-10 (table), 4-9
waveform generation timing
connections, 4-40
F
factory configuration. See USER/FACTORY
configuration.
GPCTR0_SOURCE signal, 4-38 to 4-39
GPCTR0_UP_DOWN signal, 4-40
GPCTR1_GATE signal, 4-41 to 4-42
GPCTR1_OUT signal
fax support, D-2
FaxBack support, D-2
field wiring considerations, 4-45
floating signal sources
description (table), 4-4
VXI-MIO-64E-1 (table), 4-7
VXI-MIO-64XE-10 (table), 4-8
waveform generation timing connections,
4-42 to 4-43
description, 4-11
differential connections, 4-16 to 4-17
recommended configuration
(figure), 4-13
GPCTR1_SOURCE signal, 4-41
GPCTR1_UP_DOWN signal, 4-43 to 4-44
ground-referenced signal sources
description, 4-11
single-ended connections (RSE
configuration), 4-19
FREQ_OUT signal
description (table), 4-5
differential connections, 4-15
recommended configuration
(figure), 4-13
single-ended connections (NRSE
configuration), 4-19 to 4-20
VXI-MIO-64E-1 (table), 4-7
VXI-MIO-64XE-10 (table), 4-9
waveform generation timing
connections, 4-44
frequently asked questions. See questions
about VXI-MIO series.
FTP support, D-1
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Index
NRSE (table), 3-3
RSE (table), 3-3
common-mode signal rejection, 4-20
differential connections
H
hardware installation, 2-8 to 2-9
hardware overview
analog input, 3-3 to 3-9
DIFF input configuration, 4-14
considerations for selecting input
ranges, 3-6
dither, 3-7 to 3-8
floating signal sources, 4-16 to 4-17
ground-referenced signal
sources, 4-15
nonreferenced signal sources,
4-16 to 4-17
input modes, 3-3 to 3-4
input polarity and range, 3-4 to 3-6
multichannel scanning
considerations, 3-8 to 3-9
analog output, 3-10 to 3-11
output polarity selection,
3-10 to 3-11
reference selection, 3-10
reglitch selection, 3-11
analog trigger, 3-11 to 3-14
above-high-level analog triggering
mode (figure), 3-13
recommended configuration
(figure), 4-13
single-ended connections, 4-18 to 4-20
floating signal sources (RSE
configuration), 4-19
grounded signal sources (NRSE
configuration), 4-19 to 4-20
input polarity and range, 3-4 to 3-6
mixing bipolar and unipolar channels
(note), 3-5
below-low-level analog triggering
mode (figure), 3-12
block diagram, 3-12
high-hysteresis analog triggering
mode (figure), 3-13
inside-region analog triggering mode
(figure), 3-13
selection considerations, 3-6
VXI-MIO-64E-1, 3-4 to 3-5
actual range and measurement
precision (table), 3-4 to 3-5
VXI-MIO-64XE-10, 3-5 to 3-6
actual range and measurement
precision (table), 3-6
low-hysteresis analog triggering
mode (figure), 3-14
installation. See also configuration.
common questions about, C-2
hardware installation, 2-8 to 2-9
software installation, 2-9 to 2-10
unpacking VXI-MIO series boards, 1-6
I/O connectors, 4-1 to 4-9
exceeding maximum ratings
(warning), 4-1
digital I/O, 3-14
timing signal routing, 3-15 to 3-16
CONVERT* signal routing
(figure), 3-15
programmable function inputs, 3-16
VXIbus triggers, 3-17
optional cable connectors
68-pin extended analog input
connector pin assignments
(figure), B-3
68-pin MIO connector pin
assignments (figure), B-2
pin assignments (figure), 4-2
signal descriptions (table), 4-3 to 4-5
I
input characteristics
VXI-MIO-64E-1, A-1 to A-2
VXI-MIO-64XE-10, A-10
input configurations, 4-12 to 4-20
available input modes, 3-3 to 3-4
DIFF (table), 3-3
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PFI2/CONVERT* signal
description (table), 4-4
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
PFI3/GPCTR1_SOURCE signal
description (table), 4-4
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
PFI4/GPCTR1_GATE signal
description (table), 4-4
L
LabVIEW and LabWindows/CVI
software, 1-3
M
manual. See documentation.
memory. See SIMM size configuration.
multichannel scanning, 3-8 to 3-9
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-9
PFI5/UPDATE* signal
N
NI-DAQ driver software, 1-3 to 1-4
noise, avoiding, 4-45
description (table), 4-5
NRSE (nonreferenced single-ended input)
description (table), 3-3
VXI-MIO-64E-1 (table), 4-7
VXI-MIO-64XE-10 (table), 4-9
PFI6/WFTRIG signal
differential connections, 4-16 to 4-17
recommended configuration
(figure), 4-13
single-ended connections (NRSE
configuration), 4-19 to 4-20
description (table), 4-5
VXI-MIO-64E-1 (table), 4-7
VXI-MIO-64XE-10 (table), 4-9
PFI7/STARTSCAN signal
description (table), 4-5
VXI-MIO-64E-1 (table), 4-7
VXI-MIO-64XE-10 (table), 4-9
PFI8/GPCTR0_SOURCE signal
description (table), 4-5
VXI-MIO-64E-1 (table), 4-7
VXI-MIO-64XE-10 (table), 4-9
PFI9/GPCTR0_GATE signal
description (table), 4-5
O
onboard EEPROM. See EEPROM.
operation of VXI-MIO series boards. See
hardware overview.
output characteristics
VXI-MIO-64E-1, A-5
VXI-MIO-64XE-10, A-13
VXI-MIO-64E-1 (table), 4-7
VXI-MIO-64XE-10 (table), 4-9
PFIs (programmable function inputs),
4-24 to 4-25
P
parts locator diagrams, 2-3, 2-4
PFI0/TRIG1 signal
common questions about, C-5 to C-6
overview, 4-23
signal routing, 3-16
timing input connections, 4-24 to 4-25
illustration, 4-24
description (table), 4-4
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
PFI1/TRIG2 signal
description (table), 4-4
PGIA (programmable gain instrumentation
amplifier)
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
analog input connections, 4-10 to 4-11
illustration, 4-10
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common-mode signal rejection, 4-20
differential connections
reglitch selection, 3-11
RSE (referenced single-ended input)
description (table), 3-3
floating signal sources, 4-16 to 4-17
ground-referenced signal
sources, 4-15
recommended configuration
(figure), 4-13
single-ended connections
single-ended connections for floating
signal sources, 4-19
floating signal sources (figure), 4-19
grounded signal sources
(figure), 4-20
physical specifications
S
SCANCLK signal
VXI-MIO-64E-1, A-9
description (table), 4-4
VXI-MIO-64XE-10, A-16
pin assignments. See I/O connectors.
polarity
input polarity and range, 3-4 to 3-6
output polarity selection, 3-10 to 3-11
posttriggered data acquisition, 4-25
illustration, 4-25
power connections, 4-23
power requirement specifications
VXI-MIO-64E-1, A-9
VXI-MIO-64XE-10, A-16
pretriggered data acquisition, 4-25
illustration, 4-26
programmable function inputs (PFIs). See
PFIs (programmable function inputs).
programmable gain instrumentation amplifier.
See PGIA (programmable gain
instrumentation amplifier).
timing connections, 4-26
VXI-MIO-64E-1 (table), 4-6
VXI-MIO-64XE-10 (table), 4-8
settling time, 3-9
signal connections
analog input, 4-9 to 4-20
analog output, 4-20 to 4-21
digital I/O, 4-22 to 4-23
field wiring considerations, 4-45
input configurations, 4-12 to 4-20
common-mode signal rejection, 4-20
differential connections
DIFF input configuration, 4-14
floating signal sources,
4-16 to 4-17
ground-referenced signal
sources, 4-15
nonreferenced signal sources,
4-16 to 4-17
Q
recommended configuration
(figure), 4-13
single-ended connections, 4-18 to 4-20
floating signal sources (RSE
configuration), 4-19
questions about VXI-MIO series, C-1 to C-6
analog input and analog output,
C-2 to C-4
general information, C-1 to C-2
installation and configuration, C-2
timing and digital I/O, C-4 to C-6
grounded signal sources (NRSE
configuration), 4-19 to 4-20
I/O connector, 4-1 to 4-9
exceeding maximum ratings
(warning), 4-1
R
reference selection, analog output, 3-10
referenced single-ended input (RSE). See RSE
(referenced single-ended input).
pin assignments (figure), 4-2
signal descriptions (table),
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4-3 to 4-5
waveform generation timing
connections, 4-34 to 4-38
UISOURCE signal,
power connections, 4-23
timing connections, 4-23 to 4-44
data acquisition timing
connections, 4-25 to 4-34
AIGATE signal,
4-37 to 4-38
UPDATE* signal,
4-36 to 4-37
4-33 to 4-34
CONVERT* signal,
4-32 to 4-33
WFTRIG signal, 4-34
types of signal sources, 4-11
floating, 4-11
EXTSTROBE* signal, 4-26
to 4-27
SCANCLK signal, 4-26
SISOURCE signal, 4-34
STARTSCAN signal, 4-30
to 4-31
ground-referenced, 4-11
SIMM size configuration, 2-5 to 2-6
accessing SIMM sockets, 2-6
DRAM configuration (table), 2-6 to 2-7
single-ended connections
description, 4-18
TRIG1 signal, 4-27 to 4-28
TRIG2 signal, 4-28 to 4-29
typical posttriggered
acquisition (figure), 4-25
typical pretriggered
acquisition (figure), 4-26
general-purpose timing signal
connections, 4-38 to 4-44
FREQ_OUT signal, 4-44
GPCTR0_GATE signal,
4-39 to 4-40
floating signal sources (RSE), 4-19
grounded signal sources (NRSE),
4-19 to 4-20
when to use, 4-18
SISOURCE signal, 4-34
software
installation, 2-9 to 2-10
programming choices
ComponentWorks, 1-2
LabVIEW and LabWindows/CVI,
1-3
GPCTR0_OUT signal, 4-40
GPCTR0_SOURCE signal,
4-38 to 4-39
NI-DAQ driver software, 1-3 to 1-4
VirtualBench, 1-3
specifications
GPCTR0_UP_DOWN
signal, 4-40
GPCTR1_GATE signal,
4-41 to 4-42
GPCTR1_OUT signal, 4-42
to 4-43
VXI-MIO-64E-1
analog input, A-1 to A-4
amplifier characteristics, A-3
dynamic characteristics, A-4
input characteristics, A-1 to A-2
stability, A-4
GPCTR1_SOURCE signal,
4-41
GPCTR1_UP_DOWN
signal, 4-43 to 4-44
programmable function input
connections, 4-24 to 4-25
transfer characteristics, A-3
analog output, A-5 to A-7
dynamic characteristics, A-6
output characteristics, A-5
stability, A-6 to A-7
transfer characteristics,
A-5 to A-6
voltage output, A-6
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digital I/O, A-7
environment, A-9
physical, A-9
power requirements, A-9
timing I/O, A-7 to A-8
triggers, A-8
T
technical support, D-1 to D-2
theory of operation. See hardware overview.
timebase, 3-16
timing connections, 4-23 to 4-44
common questions about, C-4 to C-6
data acquisition timing connections, 4-25
to 4-34
analog trigger, A-8
digital trigger, A-8
VXIbus, A-8
AIGATE signal, 4-33 to 4-34
CONVERT* signal, 4-32 to 4-33
EXTSTROBE* signal, 4-26 to 4-27
SCANCLK signal, 4-26
SISOURCE signal, 4-34
STARTSCAN signal, 4-30 to 4-31
TRIG1 signal, 4-27 to 4-28
TRIG2 signal, 4-28 to 4-29
typical posttriggered acquisition
(figure), 4-25
VXI-MIO-64XE-10
analog input, A-10 to A-12
amplifier characteristics, A-11
dynamic characteristics, A-12
input characteristics, A-10
stability, A-12
transfer characteristics, A-11
analog output, A-13 to A-14
dynamic characteristics, A-13
output characteristics, A-13
stability, A-14
transfer characteristics, A-13
voltage output, A-13
digital I/O, A-14
environment, A-16
physical, A-16
power requirement, A-16
timing I/O, A-15
triggers
typical pretriggered acquisition
(figure), 4-26
general-purpose timing signal
connections, 4-38 to 4-44
FREQ_OUT signal, 4-44
GPCTR0_GATE signal,
4-39 to 4-40
GPCTR0_OUT signal, 4-40
GPCTR0_SOURCE signal,
4-38 to 4-39
GPCTR0_UP_DOWN
signal, 4-40
GPCTR1_GATE signal,
4-41 to 4-42
GPCTR1_OUT signal,
analog trigger, A-15 to A-16
digital trigger, A-16
VXIbus, A-16
stability
analog input specifications
VXI-MIO-64E-1, A-4
4-42 to 4-43
VXI-MIO-64XE-10, A-12
analog output specifications
VXI-MIO-64E-1, A-6 to A-7
VXI-MIO-64XE-10, A-14
STARTSCAN signal timing connections,
4-30 to 4-31
GPCTR1_SOURCE signal, 4-41
GPCTR1_UP_DOWN signal,
4-43 to 4-44
programmable function input
connections, 4-24 to 4-25
timing I/O connections (figure), 4-24
input timing (figure), 4-30
output timing (figure), 4-31
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Index
waveform generation timing
connections, 4-34 to 4-38
UISOURCE signal, 4-37 to 4-38
UPDATE* signal, 4-36 to 4-37
WFTRIG signal, 4-34
specifications
VXI-MIO-64E-1
analog trigger, A-8
digital trigger, A-8
VXIbus, A-8
timing I/O specifications
VXI-MIO-64E-1, A-7 to A-8
VXI-MIO-64XE-10, A-15
timing signal routing, 3-15 to 3-16
CONVERT* signal routing (figure), 3-15
programmable function inputs, 3-16
timebase, 3-16
VXI-MIO-64XE-10
analog trigger, A-15 to A-16
digital trigger, A-16
VXIbus, A-16
VXIbus triggers, 3-17
troubleshooting. See questions about
VXI-MIO series.
VXIbus triggers, 3-17
transfer characteristics
U
analog input
UISOURCE signal, 4-37 to 4-38
unipolar input, mixing with bipolar channels
(note), 3-5
unipolar output, 3-10 to 3-11
unpacking VXI-MIO series boards, 1-6
UPDATE* signal timing connections,
4-36 to 4-37
input timing (figure), 4-37
output timing (figure), 4-37
USER/FACTORY configuration
loading, 2-7 to 2-8
VXI-MIO-64E-1, A-3
VXI-MIO-64XE-10, A-11
analog output
VXI-MIO-64E-1, A-5 to A-6
VXI-MIO-64XE-10, A-13
TRIG1 signal timing connections, 4-27 to 4-28
input timing (figure), 4-28
output timing (figure), 4-28
TRIG2 signal timing connections, 4-28 to 4-29
input timing (figure), 4-29
output timing (figure), 4-29
triggers
protecting/changing factory
configuration, 2-8
analog, 3-11 to 3-14
above-high-level triggering mode
(figure), 3-13
below-low-level triggering mode
(figure), 3-12
block diagram, 3-12
high-hysteresis triggering
mode, 3-13
inside-region triggering mode
(figure), 3-13
low-hysteresis triggering mode, 3-14
V
VirtualBench software, 1-3
voltage output
VXI-MIO-64E-1, A-6
VXI-MIO-64XE-10, A-13
VXIbus logical address, 2-1 to 2-2
selecting (figure), 2-5
VXIbus triggers, 3-17
specifications
VXI-MIO-64E-1, A-8
VXI-MIO-64XE-10, A-16
trigger line utilization (figure), 3-17
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Index
VXI-MIO series. See also hardware overview.
common questions about, C-1 to C-6
custom cabling, 1-6
W
waveform generation timing connections,
4-34 to 4-38
features, 1-1
optional equipment, 1-5
requirements for getting started, 1-2
software programming choices
ComponentWorks, 1-2
UISOURCE signal, 4-37 to 4-38
UPDATE* signal, 4-36 to 4-37
WFTRIG signal, 4-34
WFTRIG signal timing connections, 4-35
input timing (figure), 4-35
output timing (figure), 4-35
wiring considerations, 4-45
LabVIEW and LabWindows/CVI,
1-3
NI-DAQ driver software, 1-3 to 1-4
VirtualBench, 1-3
unpacking, 1-6
VXIplug&play instrument drivers,
1-4 to 1-5
VXIplug&play instrument drivers, 1-4 to 1-5
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