Tektronix vx4380 Drums User Manual

Tektronix vx4380 Drums User Manual
User Manual
VX4380
256-Crosspoint Relay Matrix Module
070-9182-03
This document supports firmware version 1.00
and above.
Warning
The servicing instructions are for use by qualified
personnel only. To avoid personal injury, do not
perform any servicing unless you are qualified to
do so. Refer to the Safety Summary prior to
performing service.
Copyright Tektronix, Inc. 1995. All rights reserved. Licensed software products are owned by Tektronix or its suppliers
and are protected by United States copyright laws and international treaty provisions.
Use, duplication, or disclosure by the Government is subject to restrictions as set forth in subparagraph (c)(1)(ii) of the
Rights in Technical Data and Computer Software clause at DFARS 252.227-7013, or subparagraphs (c)(1) and (2) of the
Commercial Computer Software – Restricted Rights clause at FAR 52.227-19, as applicable.
Tektronix products are covered by U.S. and foreign patents, issued and pending. Information in this publication supercedes
that in all previously published material. Specifications and price change privileges reserved.
Printed in the U.S.A.
Tektronix, Inc., P.O. Box 1000, Wilsonville, OR 97070–1000
TEKTRONIX and TEK are registered trademarks of Tektronix, Inc.
VXIbus is a trademark of the VXI Consortium.
SurePath and Intelliframe are registered trademarks of Tektronix, Inc.
WARRANTY
Tektronix warrants that this product will be free from defects in materials and workmanship for a period of three (3) years
from the date of shipment. If any such product proves defective during this warranty period, Tektronix, at its option, either
will repair the defective product without charge for parts and labor, or will provide a replacement in exchange for the
defective product.
In order to obtain service under this warranty, Customer must notify Tektronix of the defect before the expiration of the
warranty period and make suitable arrangements for the performance of service. Customer shall be responsible for
packaging and shipping the defective product to the service center designated by Tektronix, with shipping charges prepaid.
Tektronix shall pay for the return of the product to Customer if the shipment is to a location within the country in which the
Tektronix service center is located. Customer shall be responsible for paying all shipping charges, duties, taxes, and any
other charges for products returned to any other locations.
This warranty shall not apply to any defect, failure or damage caused by improper use or improper or inadequate
maintenance and care. Tektronix shall not be obligated to furnish service under this warranty a) to repair damage resulting
from attempts by personnel other than Tektronix representatives to install, repair or service the product; b) to repair
damage resulting from improper use or connection to incompatible equipment; or c) to service a product that has been
modified or integrated with other products when the effect of such modification or integration increases the time or
difficulty of servicing the product.
THIS WARRANTY IS GIVEN BY TEKTRONIX WITH RESPECT TO THIS PRODUCT IN LIEU OF ANY
OTHER WARRANTIES, EXPRESSED OR IMPLIED. TEKTRONIX AND ITS VENDORS DISCLAIM ANY
IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
TEKTRONIX’ RESPONSIBILITY TO REPAIR OR REPLACE DEFECTIVE PRODUCTS IS THE SOLE AND
EXCLUSIVE REMEDY PROVIDED TO THE CUSTOMER FOR BREACH OF THIS WARRANTY. TEKTRONIX
AND ITS VENDORS WILL NOT BE LIABLE FOR ANY INDIRECT, SPECIAL, INCIDENTAL, OR
CONSEQUENTIAL DAMAGES IRRESPECTIVE OF WHETHER TEKTRONIX OR THE VENDOR HAS
ADVANCE NOTICE OF THE POSSIBILITY OF SUCH DAMAGES.
Table of Contents
General Safety Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Preface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
iii
vii
Getting Started . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Product Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Controls and Indicators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Installation Checklist . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Functional Check . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1–1
1–1
1–5
1–5
1–7
1–8
1–10
1–11
Operating Basics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Functional Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Power-on . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Instrument I/O: VXIbus Basics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2–1
2–1
2–1
2–2
Getting Started
Operating Basics
Syntax and Commands
Command Syntax . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Functional Command Groups . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
System Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Module Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Command Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
IEEE-488.2 Common Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3–1
3–11
3–11
3–11
3–15
3–53
Status and Events . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Status and Event Reporting System . . . . . . . . . . . . . . . . . . . . . . . . . . .
4–1
4–1
Status and Events
Status Byte Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Service Request Enable Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Standard Event Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Event Status Enable Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
The Output Queue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
The System Error and Event Queue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Status and Event Reporting Process . . . . . . . . . . . . . . . . . . . . . . . . . . .
Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VX4380 256-Crosspoint Relay Matrix Module User Manual
4–1
4–2
4–3
4–4
4–4
4–4
4–5
4–6
i
Table of Contents
Appendices
Appendix A: Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Appendix B: Input/Output Connections . . . . . . . . . . . . . . . . . . . . . . . .
Appendix C: Examples . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Appendix D: User Service . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Appendix E: Replaceable Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Parts Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Using the Replaceable Parts List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
A–1
B–1
C–1
D–1
E–1
E–1
E–2
Glossary and Index
ii
VX4380 256-Crosspoint Relay Matrix Module User Manual
General Safety Summary
Review the following safety precautions to avoid injury and prevent damage to
this product or any products connected to it.
To avoid potential hazards, use this product only as specified.
Only qualified personnel should perform service procedures.
While using this product, you may need to access other parts of the system. Read
the General Safety Summary in other system manuals for warnings and cautions
related to operating the system.
Injury Precautions
Avoid Electric Overload
Avoid Electric Shock
To avoid electric shock or fire hazard, do not apply a voltage to a terminal that is
outside the range specified for that terminal.
To avoid injury or loss of life, do not disconnect probes or test leads from this
product while it is connected to a voltage source.
Do Not Operate Without
Covers
To avoid electric shock or fire hazard, do not operate this product with covers or
panels removed.
Use Proper Fuse
To avoid fire hazard, use only the fuse type and rating specified for this product.
Do Not Operate in
Wet/Damp Conditions
Do Not Operate in an
Explosive Atmosphere
Avoid Exposed Circuitry
To avoid electric shock, do not operate this product in wet or damp conditions.
To avoid injury or fire hazard, do not operate this product in an explosive
atmosphere.
To avoid injury, remove jewelry such as rings, watches, and other metallic
objects. Do not touch exposed connections and components when power is
present.
Product Damage Precautions
Provide Proper Ventilation
To prevent product overheating, provide proper ventilation.
VX4380 256-Crosspoint Relay Matrix Module User Manual
iii
General Safety Summary
Do Not Operate With
Suspected Failures
If you suspect there is damage to this product, have it inspected by qualified
service personnel.
Safety Terms and Symbols
Terms in This Manual
These terms may appear in this manual:
WARNING. Warning statements identify conditions or practices that could result
in injury or loss of life.
CAUTION. Caution statements identify conditions or practices that could result in
damage to this product or other property.
Terms on the Product
These terms may appear on the product:
DANGER indicates an injury hazard immediately accessible as you read the
marking.
WARNING indicates an injury hazard not immediately accessible as you read the
marking.
CAUTION indicates a hazard to property including the product.
Symbols on the Product
The following symbols may appear on the product:
DANGER
High Voltage
Protective Ground
(Earth) Terminal
ATTENTION
Refer to Manual
Double
Insulated
Certifications and Compliances
Safety Certification of
Plug-in or VXI Modules
For modules (plug-in or VXI) that are safety certified by Underwriters Laboratories, UL Listing applies only when the module is installed in a UL Listed
product.
For modules (plug-in or VXI) that have cUL or CSA approval, the approval
applies only when the module is installed in a cUL or CSA approved product.
iv
VX4380 256-Crosspoint Relay Matrix Module User Manual
General Safety Summary
Compliances
Overvoltage Category
Consult the product specifications for Overvoltage Category, and Safety Class.
The following defines overvoltage categories:
CAT III: Distribution level mains, fixed installation.
CAT II: Local level mains, appliances, portable equipment
CAT I: Signal level, special equipment or parts of equipment, telecommunication, electronics
VX4380 256-Crosspoint Relay Matrix Module User Manual
v
General Safety Summary
vi
VX4380 256-Crosspoint Relay Matrix Module User Manual
Preface
This manual assumes you are familiar with VXIbus instruments and operation
and with the purpose and function of this instrument.
Please read and follow all instructions for installation and configuration. Use the
Installation Checklist to ensure proper installation and to record your initial
settings.
The Operating Basics section gives a summary of VXIbus operation and
presents an overview of the operation of this instrument.
The Syntax and Commands section provides a summary of all the commands
followed by detailed descriptions of each command.
The Status and Events section contains an explanation of the Status and Event
Reporting System and lists the system messages. Appendix C: Examples contains
example programs that demonstrate the programmable features of this instrument.
You may also want to keep the Reference Guide by the instrument.
Conventions
The names of all switches, controls, and indicators appear in this manual exactly
as they appear on the instrument.
Specific conventions for programming are given in the sections Syntax and
Commands and Appendix C: Examples.
VX4380 256-Crosspoint Relay Matrix Module User Manual
vii
Preface
viii
VX4380 256-Crosspoint Relay Matrix Module User Manual
Getting Started
Getting Started
This section begins with a brief description of the VX4380 256-Crosspoint Relay
Matrix Module, and explains how to configure and install the module in a
VXIbus mainframe. The quick functional check, also included in this section,
assures that the instrument operates properly.
Product Description
The VX4380 256-Crosspoint Relay Matrix Module is a printed circuit board
assembly for use in a mainframe conforming to the VXIbus Specification. The
VX4380 provides four 4 × 16 2-wire matrix sections. Each section can be
configured to connect either the four rows or the sixteen columns to the section
above or below it to produce up to a 16 × 16 2-wire matrix or a 4 × 64 2-wire
matrix. The VX4380 provides the following features:
H
high density single slot VXI relay matrix module with four 2-wire matrices
H
2 A switching maximum current per contact
H
220 VDC, 250 VAC maximum switching voltage per contact
H
60 W, 125 VA maximum switching power per contact
H
latching relays for low-power, low-noise operation
H
two 160-pin DIN front panel connectors
H
low-cost VXI local bus slave interface
H
Option 01 – this option enables the VX4380 to control up to 11 additional
relay modules from the Tektronix family of relay modules. These modules
are controlled via the VXI P2 local bus.
H
> 15 MHz bandwidth (– 3 dB) for 4 × 16 2-wire matrix
H
> 15 MHz bandwidth (– 3 dB) for 16 × 16 2-wire matrix
User control of the VX4380 is achieved by installing the Option 01 VXI
Interface daughter board. This daughter board may be installed on the VX4380
or on another Tektronix compatible relay module which is installed in a VXI
chassis slot to the left of the VX4380. The Option 01 daughter board acts as a
VXI servant to a VXI bus commander. The VXI bus commander sends SCPI
compatible commands to the Option 01 daughter board using VXI word serial
protocol. The Option 01 daughter board in turn controls the VX4380 on which it
is installed and controls additional relay modules installed in adjacent slots to its
right via the VXI P2 local bus. The daughter board is capable of controlling from
VX4380 256-Crosspoint Relay Matrix Module User Manual
1–1
Getting Started
one to 12 relay modules including members of the SurePatht family of relay
switching modules and VX4372 and VX4374 Scanner Slave modules. In this
document, these modules will be referred to as “local bus slaves.”
The Option 01 VXI Interface Module includes the following features:
H
CPU:
Zilog Z88C00 Microcontroller with 20 MHz clock
64 Kbyte of EPROM and 32 Kbyte of RAM
H
VXI Interface:
VXI Rev 1.4 Message Based Device
Supports Fast Handshake word serial protocol data transfers
IEEE-488.2 device
Logical Address selectable with two rotary hexadecimal switches
Interrupter level selectable with a rotary hexadecimal switch. Selects one of
seven levels or disables interrupt generation
Command programmable control of one to eight VXI TTL trigger
Command programmable monitoring of one of eight VXI TTL triggers
The Local Bus Interface provides serial I/O interface for control of VX4372 and
VX4374 Scanner Slave and SurePatht relay modules, monitors the power fuses
of all local bus slave modules that it controls, and provides a serial input
interface to identify each local bus slave that it controls.
As part of the self test, SurePatht modules automatically verify the control
logic every time a relay operation is performed.
Figure 1–1 shows a functional block diagram of the VX4380. Figure 1–2 shows
a typical SurePatht configuration.
1–2
VX4380 256-Crosspoint Relay Matrix Module User Manual
Getting Started
Join Rows
1–4
4 x 16
=
4
...
3
...
2
...
1
...
1
2
3
Section 4
4 x 16 2-Wire
Join Cols
3–4
Join Rows
3–4
Section 3
4 x 16 2-Wire
Join Rows
2–3
Join Cols
2–3
16
Section 2
4 x 16 2-Wire
=
Join Rows
1–2
Join Cols
1–2
Section 1
4 x 16 2-Wire Matrix
1
2
3
4
4 x 16
4 x 16
4 x 16
4 x 16
4 x 16
4
4 x 16
3
4 x 64
2
4 x 16
4 x 16
3
4 x 16
2
1
4 x 16
4 x 16
4
4 x 16
1
8 x 32
16 x 16
Figure 1–1: VX4380 Functional Block Diagram
VX4380 256-Crosspoint Relay Matrix Module User Manual
1–3
Getting Started
VXI interface &
slave controller
daughter board
Backplane
connectors
Front panel
connectors
VXI backplane
local bus
Daughter board
connectors
Figure 1–2: Typical SurePath Configuration
Fuses
The VX4380 Module has one 10 A fast-acting fuse on the +5 V line.
Each relay module that the Option 01 Module controls has a fuse that limits the
amount of current that the module can draw from the VXI backplane +5 V power
pins. This fuse protects the module in case of an accidental shorting of the power
bus or any other situation where excessive current might be drawn.
The Option 01 Module monitors the state of the fuses of each of the relay
modules that it controls. If a fuse opens on one of these modules, the Option 01
Module will assert SYSFAIL* on the VXIbus.
If the +5 V fuse on the module on which the Option 01 Module is installed
opens, the VXIbus Resource Manager will be unable to assert SYSFAIL
INHIBIT on the Option 01 to disable SYSFAIL*.
If a +5 V fuse opens, remove the fault before replacing the fuse. Replacement
fuse information is given in the Specifications section of the user manual for the
appropriate relay module.
1–4
VX4380 256-Crosspoint Relay Matrix Module User Manual
Getting Started
LEDs
BITE (Built-in Test
Equipment)
The following LEDs are visible at the top of the VX4380 Module’s front panel to
indicate the status of the module’s operation (see Figure 1–5).
Power LED
indicates power is applied to the module
Failed LED
indicates the module is in the FAILED state
Built-in Test Equipment (BITE) is provided by extensive self tests that are
automatically invoked on power-on and can also be invoked on command.
Circuitry tested includes the CPU and all memory, and the relay control circuitry
on each relay module controlled by the Option 01.
Accessories
Table 1–1 lists the standard accessories included with the VX4380.
Table 1–1: Standard Accessories
Accessory
Part Number
VX4380 User Manual
070-9182-XX
VX4380 Reference
070-9202-XX
Table 1–2 lists the options available for the VX4380.
Table 1–2: Options
Option
Part Number
01 VXI Interface Kit
040-1510-XX
Controls and Indicators
The following controls are provided to select the functions of the VX4380
operating environment. Figures 1–3 and 1–4 illustrate the physical location of
these controls and indicators.
Switches
The Logical Address switches and VMEbus Interrupt Level Select switch must be
correctly set to insure proper operation. See Configuration for details on how to
set the switches.
VX4380 256-Crosspoint Relay Matrix Module User Manual
1–5
Getting Started
LOGICAL
ADDRS
LO
Option 01
HI
INTRPT
Switches as viewed
from the rear of instrument
(labels are on the back shield)
F1291
Figure 1–3: VX4380 Connectors, Indicators, and Switch Locations
Figure 1–4: VX4380 Front Panel
1–6
VX4380 256-Crosspoint Relay Matrix Module User Manual
Getting Started
Configuration
The following switches must be correctly set to ensure proper operation. Refer to
Figure 1–3 for their physical locations.
Logical Address Switches
Each functional module in a VXIbus System must be assigned a unique logical
address, from 1 to decimal 255 (hexadecimal FF). The base VMEbus address of
the VX4380 is set to a value between 1 and hexadecimal FF (FF16) by two
hexadecimal rotary switches. Align the desired switch position with the arrow on
the module shield.
The physical address of the instrument is on a 64 byte boundary. If the Logical
Address switch representing the most significant digit (LA-HI) of the logical
address is set to position X and the switch representing the least significant digit
(LA-LO) of the logical address is set to position Y, then the base physical
address of the VX4380 will be [(4016 × XY16) + C00016]. For example:
Base Physical Address
L.A.
HI
LO
decimal
hex
A16
016
A16
(64 * 10) + 49152 = 49792
(4016 * A16) + C00016 = C28016
1516
116
516
(64 * 21) + 49152 = 50496
(4016 * 1516) + C00016 = C54016
LA. is the Logical Address
IEEE-488 Address
In order to use and program the VX4380 Module in an IEEE-488 environment
you must know the IEEE-488 address of the module. Different manufacturers of
IEEE-488 interface devices might have different algorithms for equating a
logical address with an IEEE-488 address. Consult the operating manual of the
IEEE-488 Interface Module being used.
VMEbus Interrupt Level
Select Switch
Each function module in a VXIbus System can generate an interrupt at a
specified level on the VMEbus to request service from the interrupt handler
located on its commander. Set the interrupt level to the same level as the
interrupt handler on that commander. The VMEbus interrupt level on which the
VX4380 Module generates interrupts is set by a rotary switch. Align the desired
switch position with the arrow on the module shield.
Valid VMEbus Interrupt Level Select switch settings are one through seven, with
setting one equivalent to level one, and so on. The level chosen should be the
same as the level set on the VX4380 interrupt handler, typically the module
commander. Setting the switch to zero or eight will disable the module interrupts. Do not use switch settings nine through f.
VX4380 256-Crosspoint Relay Matrix Module User Manual
1–7
Getting Started
Interrupts are used by the module to return VXIbus Protocol Events to the
module commander. Refer to the Operating Basics section for more information
on interrupts. The VXIbus Protocol Events supported by the module are listed in
Appendix A: Specifications.
Installation
This section describes how to install the VX4380.
Tools Required
Requirements and
Cautions
A slotted screwdriver set is required for proper installation.
The VX4380 Module is a C-size VXIbus instrument module and therefore may
be installed in any C- or D-size VXIbus mainframe slot other than slot 0. To
install the module in a D-size mainframe, consult the operating manual for the
mainframe. Refer to Configuration for information on selecting and setting the
Logical Address switch of the module. This switch defines the programming
address of your module. To avoid confusion, it is recommended that the slot
number and the logical address be the same.
NOTE. Note that there are two printed ejector handles on the card. To avoid
installing the card incorrectly, make sure the ejector marked “VX4380” is at the
top.
Verify that the mainframe is able to provide adequate cooling and power with
this module installed. Refer to the mainframe Operating Manual for instructions.
If the VX4380 is used in a Tektronix mainframe, all VX4380 cooling requirements are met
If the VX4380 is inserted in a slot with any empty slots to the left of the module,
the VME daisy-chain jumpers must be installed on the backplane in order for the
VXI Module to operate properly. Check the manual of the mainframe being used
for jumpering instructions. Jumpers are not necessary for autoconfiguring
backplane designs.
1–8
VX4380 256-Crosspoint Relay Matrix Module User Manual
Getting Started
Installation Procedure
Follow these steps to install the VX4380. If the module has Option 01, first refer
to the Option 01 User Manual for instructions on mounting the option.
CAUTION. The VX4380 Module is a piece of electronic equipment and therefore
has some susceptibility to electrostatic damage (ESD). ESD precautions must be
taken whenever the module is handled.
1. Record the revision level, serial number (located on the label on the shield of
the VX4380), and switch settings on the Installation Checklist.
2. Verify that the switches are set to the correct values. Refer to Configuration
for more information on setting switches.
3. Make sure that the mainframe power is off.
4. Insert the module into one of the instrument slots of the mainframe (see
Figure 1–5).
5. Cable Installation: Use the correct cable to interface between the module I/O
connector and the Unit Under Test (UUT). The recommended cable is listed
in Appendix A: Specifications.
Figure 1–5: Module Installation
VX4380 256-Crosspoint Relay Matrix Module User Manual
1–9
Getting Started
Installation Checklist
Installation parameters will vary depending on the mainframe being used. Be
sure to consult the mainframe operating manual before installing and operating
the module.
Revision Level: ___________
Serial No.: ___________
Mainframe Slot Number: ___________
Switch Settings: ___________
VXIbus Logical Address Switch: ___________
Interrupt Level Select Switch: ___________
Cable Installed (if any): ___________
Performed by: _______________________
1–10
Date: _____________
VX4380 256-Crosspoint Relay Matrix Module User Manual
Getting Started
Functional Check
In addition to the self tests, you can also perform an operational check of the
VX4380.
Self Test
The VX4380 256-Crosspoint Relay Matrix Module executes a self test at
power-on, on direction of a VXIbus hard or soft reset condition, or on command.
The power-on self test consists of an interface self test and an instrument self
test. The self test requested by command performs only the instrument self test.
A VXIbus hard reset occurs when another device, such as the VXIbus Resource
Manager, asserts the backplane line SYSRESET*. A VXIbus soft reset occurs
when another device, such as the VX4380 commander, sets the Reset bit in the
VX4380 Control register.
During power-on, or a hard or soft reset, the following actions take place:
1. The SYSFAIL* (VME system-failure) line is set active, indicating that the
module is executing a self test, and the Failed LED is lighted. For a soft
reset, SYSFAIL* is set. All Tektronix commanders will simultaneously set
SYSFAIL INHIBIT to prevent the resource manager from prematurely
reporting the failure of a card.
2. On completion of the interface self test, SYSFAIL* is de-asserted. If the test
fails, the SYSFAIL* line remains active. If the interface self test passed, the
SYSFAIL* line is released, and the module enters the VXIbus PASSED state
(ready for normal operation). If it failed, the module enters the VXIbus
FAILED state.
3. The instrument self test, as described in the *TST? command description, is
then executed. This tests the Option 01 VXI Interface daughter board and
any relay modules under its control. If the self test fails, the module makes
an internal record of the failure(s) that occur.
The default condition of the Option 01 Module after the completion of power-on
self test is as follows:
All relays on modules controlled by the Option 01 (except VX4320
Modules) are set to the open position.
You can run the self test at any time during normal operation by using the *TST?
command. At the end of a self test initiated by this command, the module is
restored to its pre-test state.
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Getting Started
During a commanded self test:
1. SYSFAIL* is not asserted.
2. The module executes the same instrument self test as is executed upon
power on.
3. When the self test is completed, the modules controlled by the Option 01 are
restored to their pre-test state.
Operational
Check
An operational check of the VX4380 may be performed by checking the
continuity of the switch closures using an ohmmeter or a test light.
When equipped with the Option 01 VXI Interface, the commands
will open all of the relay paths. All relays on the VX4380 will also be opened
automatically on power-on. Figure 1–1 VX4380 Functional Block Diagram
shows the configuration of the VX4380 with all paths open. Refer to Appendix
B: Input/Output Connections for the connector pinouts and the Functional Block
Diagram. Use a continuity tester to verify that all rows are open to all columns.
Will close the 2-wire switch path from row 1 of section 1 to column 1 of section
1 (Row01Lo of Section 1 to Col01Lo of Section 1, and Row01Hi of Section 1 to
Col01Hi of Section 1). Check the continuity. Be careful to prevent damage to the
pins of the front panel connectors.
Note that true measurement of the resistance of the path requires a high-resolution instrument and special procedures which are beyond the scope of this check.
Use the commands
and
to open the previous path and close the 2-wire switch path from row 1 of section
1 to column 2 of section 1. Check for continuity of the two paths.
Use the commands
and
1–12
VX4380 256-Crosspoint Relay Matrix Module User Manual
Getting Started
incrementing r (the row number) from 1 through 4 for each value of c and s
while incrementing c (the column number) from 1 through 16 for each value of s
(the section number) from 1 through 4 to close the two-wire switch path from
row r to column c of each section s. Check for continuity of the two paths each
time.
By testing in this manner, it can be verified that the module is operational.
SYSFAIL* Operation
SYSFAIL* becomes active during power-on, hard or soft reset, or self test, or if
the module loses any of its power voltages. When the mainframe Resource
Manager detects SYSFAIL* set, it will attempt to inhibit the line. This causes
the VX4380 256-Crosspoint Relay Matrix Module to deactivate SYSFAIL*
except when +5 V power is lost on the relay module on which it is installed.
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Getting Started
1–14
VX4380 256-Crosspoint Relay Matrix Module User Manual
Operating Basics
Operating Basics
The VX4380 256-Crosspoint Relay Matrix Module is a VXIbus message-based
instrument and communicates using the VXIbus Word Serial Protocol. The
module is programmed by issuing ASCII characters from the system controller
to the VX4380 via the module VXIbus commander and the VXIbus mainframe
backplane. Refer to the manual for the VXIbus device that will be the VX4380
Module commander for details on the operation of that device.
If the module commander is a Tektronix IEEE-488 Interface Module, refer to the
operating manual for the module and Appendix C: Examples in this manual for
information on how the system controller communicates with the commander
being used.
Functional Overview
The VX4380 256-Crosspoint Relay Matrix Module provides four 4 × 16 2-wire
matrix sections. Each section can be configured to connect either the four rows
or the sixteen columns to the section above or below it to produce up to a
16 × 16 2-wire matrix or a 4 × 64 2-wire matrix.
Power-on
The instrument runs its self test and is ready for programming five seconds after
power-on. The VXIbus Resource Manager can add an additional delay. The
Power LED of each relay module controlled by the Option 01 will be on. The
Failed LED on each of these modules will be off. The default condition of the
module after power-on is listed in the *RST command description. Self-test
failures are described in the *TST command description.
The format and syntax for the command strings are described in the Command
Syntax section. A complete description of each command in alphabetical order is
in the Command Descriptions section.
VX4380 256-Crosspoint Relay Matrix Module User Manual
2–1
Operating Basics
Instrument I/O: VXIbus Basics
NOTE. If the user’s mainframe has other manufacturers’ computer boards
operating in the role of VXIbus foreign devices, the assertion of BERR* (as
defined by the VXIbus Specification) may cause operating problems on these
boards.
The Option 01 Module installed on a switching module is a C-size single slot
VXIbus Message-Based Word Serial instrument. It uses the A16, D16 VME
interface available on the backplane P1 connector and does not require any A24
or A32 address space. The module is a D16 interrupter.
The Option 01 is neither a VXIbus commander nor a VMEbus master; therefore
it does not have a VXIbus Signal register. The Option 01 is a VXIbus messagebased servant.
The module supports the Normal Transfer Mode of the VXIbus using the Write
Ready, Read Ready, Data In Ready (DIR), and Data Out Ready (DOR) bits of
the module Response register.
A Normal Transfer Mode read of the Option 01 proceeds as follows:
1. The commander reads the Option 01 Response register and checks if the
Write Ready and DOR bits are true. If they are, the commander proceeds to
the next step. If not, the commander continues to poll these bits until they
become true.
2. The commander writes the Byte Request command (hexadecimal 0DEFF) to
the Data Low register of the Option 01.
3. The commander reads the Option 01 Response register and checks if the
Read Ready and DOR bits are true. If they are, the commander proceeds to
the next step. If not, the commander continues to poll these bits until they
become true.
4. The commander reads the Option 01 Data Low register.
A Normal Transfer Mode write to the Option 01 proceeds as follows:
1. The commander reads the Option 01 Response register and checks if the
Write Ready and DIR bits are true. If they are, the commander proceeds to
the next step. If not, the commander continues to poll the Write Ready and
DIR bits until they are true.
2. The commander writes the Byte Available command which contains the data
(hexadecimal 0BCXX or 0BDXX, depending on the End bit) to the Data
Low register of the Option 01.
2–2
VX4380 256-Crosspoint Relay Matrix Module User Manual
Operating Basics
The module also supports the Fast Handshake Mode during readback. In this
mode, the module is capable of transferring data at optimal backplane speed
without needing the commander to test any of the handshake bits. The Option 01
asserts BERR* to switch from Fast Handshake Mode to Normal Transfer Mode,
per VXI Specification. The Option 01 Read Ready, Write Ready, DIR and DOR
bits react properly, in case the commander does not support the Fast Handshake
Mode.
A Fast Handshake Transfer Mode read of the Option 01 proceeds as follows:
1. The commander writes the Byte Request command (hexadecimal 0DEFF) to
the Option 01 Data Low register.
2. The commander reads the Option 01 Data Low register.
A Fast Handshake Transfer Mode write of the Option 01 proceeds as follows:
The commander writes the Byte Available command which contains the data
(hexadecimal 0BCXX or 0BDXX, depending on the End bit) to the Data
Low register of the Option 01. The commander may immediately write
another Byte Available command without having to check the Response
register.
The module has no registers beyond those defined for VXIbus message based
devices. All communications with the module are through the Data Low register,
the Response register, or the VXIbus interrupt cycle. Any attempt by another
module to read or write to any undefined location of the Option 01 address space
may cause incorrect operation of the module.
As with all VXIbus devices, the Option 01 has registers located within a 64 byte
block in the A16 address space. The base address of the Option 01 device
registers is determined by the device unique logical address and can be calculated as follows:
Base Address = V16 * 4016 + C00016
where V is the device logical address as set by the Logical Address switches.
Configuration Registers
Table 2–1 lists the Configuration registers and a complete description of each
register. The offset is relative to the module base address.
Table 2–1: Register Definitions
Register
Address
(hexadecimal)
Type
Value (Bits 15-0)
ID Register
0000
RO
1011 1111 1111 1101 (hexadecimal BFFD)
Device Type
0002
RO
See Device Type definition below
Status
0004
R
Defined by state of interface
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Operating Basics
Table 2–1: Register Definitions (Cont.)
Register
Address
(hexadecimal)
Type
Value (Bits 15-0)
Control
0004
W
Defined by state of interface
Offset
0006
WO
Not used
Protocol
0008
RO
1111 0111 1111 1111 (hexadecimal F7FF)
Response
000A
RO
Defined by state of the interface
Data High
000C
Data Low
000E
W
Not fixed; command-dependent
Data Low
000E
R
Not fixed; command-dependent
Not used
RO is Read Only
WO is Write Only
R is Read
W is Write
The Register Bit definitions are listed in Tables 2–2 and 2–3.
Table 2–2: Register Bit Definitions
Register
Bit Definition
ID
hexadecimal BFFD
Protocol
hexadecimal F7FF
The contents of the Device register of the Option 01 Module depends on the
model number of the relay module that it is installed on, as shown in Table 2–3.
Table 2–3: Device Register Bit Definitions
2–4
Relay Model No.
Device Register Contents
VX4320
hexadecimal FCBF
VX4330
hexadecimal F6B5
VX4350
hexadecimal F6A1
VX4380
hexadecimal F683
VX4380 256-Crosspoint Relay Matrix Module User Manual
Syntax and Commands
Command Syntax
Command protocol and syntax for the VX4380 Module are as follows:
H
A command string consists of a string of ASCII-encoded characters
terminated by a <program message terminator>. The <program message
terminator> is optional white space, followed by any one of the following
command terminations:
a line feed <LF> or new line <NL> character (hexadecimal 0A,
decimal 10)
the END bit set
the END bit with a line feed <LF> or new line <NL>
The command string is buffered until the terminator is encountered, at which
time the entire string is processed.
H
In addition to terminating a command, the semi-colon character directs the
SCPI command parser to interpret the next command with the assumption
that all characters up to and including the last colon in the previous
command have just been parsed. In the following example, the Option 01 is
installed on a VX4380 Module. Two additional VX4380 Modules are
installed in consecutive slots to the right of the first VX4380. Under these
conditions, the commands
cause all relays on all three VX4380 Modules to open. Note that each of
these commands is terminated by a line feed. An equivalent method of
sending these commands using the semi-colon character as a terminator is
After a line feed or END bit is used to terminate a command, the parser no
longer makes the assumption described above. Thus, after the command
is parsed, the command
is no longer valid.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–1
Command Syntax
In the next example, the Option 01 is installed on a VX4330 Module. Two
additional VX4330 Modules are installed in consecutive slots to the right of
the first VX4330. The commands
connect the commons of sections 1 through 6 on the first VX4330, sections 1
and 2 on the second VX4330 and sections 1 through 4 on the third VX4330.
An equivalent way to send these commands using the semi-colon as a
terminator is
Note that <LF> in these examples represents a single line feed character.
H
White space characters can be used to make a command string more
readable. These characters are ASCII-encoded bytes in the range hexadecimal 00-09 and 0B-20 (decimal 0-9 and 11-32). This range includes the
ASCII control characters and the space, but excludes the line feed <NL>.
White space characters are ignored when legally encountered in a command
string. White space is allowed anywhere in a command string, except for the
following:
Within a program mnemonic ( for example RO UTE )
Around a colon (:) mnemonic separator (for example ROUTE: CLOSE
or ROUTE :CLOSE)
Between a mnemonic and a (?) (for example CLOSE ?)
Following an asterisk (*) (for example * STB?)
Within a number (for example 12 34)
Within a module name specified in a [ROUTe:]MODule[:DEFine]
command (for example ROUTE:MODULE:DEFINE RFM UX, 1).
At least one white space character is required between a command/query
header and its associated arguments. For example in the command
the command header is the string “route:configure:join”. The arguments
associated with this command are the module name “m1” and the section list
“(1:6)”. At least one white space character must be sent before the first
argument.
3–2
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Syntax
In the query
)',+ $'* %
the query header is the string “route:close?”. The argument associated with
this query is the channel list “(@m1(1:64))”. At least one white space
character must be sent before the channel list argument.
Syntax Example
H
All characters in a command can be sent in either upper or lower case form.
H
Multiple data parameters passed by a command are separated by a comma
(,).
H
A question mark (?) following a command indicates that a response will be
returned. All responses from the module are terminated with a carriage return
<CR> and a line feed <LF> (hexadecimal 0A) character.
H
In the command descriptions, the following special characters are used.
Except for the colon (:), these characters are not part of the command and
should not be sent. If an optional field is omitted, the default for the
command is applied.
[]
Brackets indicate an optional field
|
A bar indicates a logical OR choice
:
A colon is used to separate command fields
<>
Field indicator
Capital letters indicate the minimum required characters which need to be sent.
Lower case letters are optional. For example, the syntax of the trigger source
command is given as
! ), & - - #+
- )!&
Each of the following is a valid form of this command:
+)#!! )* (, & *',) ,*
+)#!* (*',) "'$
)#! )#!',) )#!',) )#!! )',) %% #+
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–3
Command Syntax
SCPI/IEEE 488.2
Command Elements
The definition of elements used in SCPI/IEEE 488.2 commands and command
descriptions is as follows:
<NR1>ASCII integer representation of a decimal number.
<NRf> ASCII integer, fixed point or floating point representation of a decimal
number.
<module_name> A user-defined ASCII string to be associated with the local bus
address of a relay module. <module_name> strings must start with a letter and
may consist of alphanumeric characters, underscores, and digits. The maximum
length of a <module_name> is 12 characters.
<channel_spec> One or more <NR1> ASCII strings separated by “!” characters
that specify a relay on a relay module. The format of a <channel_spec> field for
each of the SurePath relay modules is:
H
VX4320 RF Multiplexer: <NR1> ! <NR1>
The range of the first <NRf> field is 1 to 4. This field specifies a relay
within one of the sections of the VX4320. The range of the second <NRf>
field is 1 to 8. This field specifies a section of the VX4320. A one-dimensional <channel_spec> may also be used to specify a channel on a VX4320
Module. The one-dimensional <channel_spec> is given by the formula:
( (section – 1 ) × 4 ) + relay.
where variables “section” and “relay” are section and relay numbers
specified in a two-dimensional <channel_spec>.
H
VX4330 Scanner/Multiplexer: <NR1> ! <NR1>
The first <NR1> field specifies a relay within the specified section. The
range of this <NR1> field depends on the current configuration of the section
of the VX4330 specified in the second <NR1> field. The range of the second
<NR1> field is 1 to 6. This field specifies a section of the VX4330.
3–4
1 – 10
4-wire
1 – 20
4-wire independent
1 – 20
2-wire
1 – 40
1-wire
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Syntax
H
VX4350 General Purpose Switching module: <NR1>
The range of this field is 1 to 64. It specifies one of 64 relays on the
VX4350.
H
VX4380 Matrix: <NR1> ! <NR1> ! <NR1>
The range of the first <NR1> field is 1 to 4. It specifies the row of a relay in
one of the sections of the VX4380. The range of the second <NR1> field is 1
to 16. It specifies the column of a relay in one of the sections of the VX4380.
The range of the third <NR1> field is 1 to 4. It specifies a section of the
VX4380. A one dimensional <channel_spec> may also be used to specify a
channel on a VX4380 Module. The one dimensional <channel_spec> is
given by the formula:
( (section – 1 ) × 64 ) + ( ( row – 1 ) × 16 ) + column
where variables “section” and “row” and “column” are section, row, and
column numbers specified in a three-dimensional <channel_spec>.
Channel_list> A list of channel numbers on one or more relay modules.
The limits on the channel numbers in a <channel_list> depend on the model
number of the relay module(s) specified in the <channel_list>. The syntax of a
<channel_list> is shown in the following diagram:
A module_name is an ASCII string that has been associated with a relay module
in a ROUTe:MODule:DEFine command. A channel_range may consist of a
single <channel_spec> or a range of <channel_spec>s. A range of <channel_spec>s is indicated by two <channel_spec>s separated by a colon (:)
character. A <channel_spec> may have one, two or three dimensions depending
on the architecture of the relay module it applies to.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–5
Command Syntax
The following are examples of valid <channel_list>s for Tektronix VX4320,
VX4330, VX4350, VX4372, VX4374, and VX4380 relay modules. In these
examples it is assumed that the Option 01 is installed on a VX4320 Module. A
VX4330, VX4350, VX4372, VX4374, and VX4380 are installed in consecutive
slots to the right of the VX4320. The default module names for the VX4320,
VX4330, VX4350, VX4372, VX4374 and VX4380 in this example are m1, m2,
m3, m4, m5, and m6 respectively. These module names may be overridden by
specifying new module names with the [ROUTe:]MODule[DEFine] command. It
is also assumed in these examples that all sections on the VX4330 Module have
been configured as 10-to-1 4-wire scanners.
3–6
<channel_list>
Channels Specified
Channel number 1 of section 2 on the VX4320 Module.
Channel number 4 in section 1 and relay number 3 in section 8
of the VX4320 Module.
Channel number 4 in sections 1 through 8 on the VX4320
Module.
Channel number 4 in sections 1 through 8 on the VX4320
Module.
Channel 1 in section 6 of the VX4330 Module.
All channels on the VX4330 Module in the following order: 1!1,
1!2, 1!3, 1!4, 1!5, 1!6, 2!1, 2!2, 2!3, 2!4, 2!5, 2!6, ... , 10!1,
10!2, 10!3, 10!4, 10!5, 10!6.
All 10 channels in section 3 of the VX4330.
All 64 channels on the VX4350
Channels 1, 2, 3, 10, 11, and 20 through 13 on the VX4350.
Channel 1 in section 2 of the VX4372.
Channel 3 in section 1 of the VX4374.
The channel that connects row 1 to column 13 in section 3 of
the VX4380.
The channel that connects row 1 to column 1 in section 2 of
the VX4380.
Same as the previous example.
The channels that connect columns 1 through 16 to row 1 in
section 1 of the VX4380.
Same as the previous example.
Channels 1!1!1, 1!1!2, 1!1!3, 1!1!4, 1!2!1, 1!2!2, 1!2!3, 1!2!4,
1!3!1, 1!3!2, 1!3!3, 1!3!4, 2!1!1, 2!1!2, 2!1!3, 2!1!4, 2!2!1,
2!2!2, 2!2!3, 2!2!4, 2!3!1, 2!3!2, 2!3!3, 2!3!4 on the VX4380
Module.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Syntax
As the <channel_list> syntax diagram shows, channels on more than one relay
module may be specified in a <channel_list>. The next example specifies
channels on three different relay modules.
<channel_list>
Channels Specified
(@m1(1!1), m2(4!6),
m6(3!13!2))
Channel 1 of section 1 on the VX4320, Channel 4 of section 6
of the VX4330, and the channel on the VX4380 that connects
row 3 to column 13 in section 2.
<list_of_lists > A list of <channel_lists> to be executed on one or more relay
modules.
The syntax of a <list_of_lists> is supported on the VX4350 and VX4380
modules and is described by the following diagram:
<list_of_lists>
,
,
,
(
@
<module_name>
(
<channel_range>
)
)
Each <channel_list> is identified by the @ character and represents a single
location in the scan sequence. The syntax contains a list of channels that are
operated simultaneously when the single location in the scan sequence is
reached.
A maximum of eight channels may be specified in each <channel_range>.
As mentioned above, the module names used in <channel_list>s may be
specified with a [ROUTe:]MODule[:DEFine] command. The command
route:module:Define rfmux, 1
changes the module name assigned to the VX4320 to “rfmux”. The following
<channel_list> can then be used to specify channels on the VX4320.
(@rfmux(3!1,2!2))
specifies channel 3 in section 1 and channel 2 in section 2 of the VX4320.
The order in which channels are specified is important in the [ROUTe:] CLOSE?
<channel_list> and [ROUTe:]OPEN? <channel_list> queries. The states of the
channels are returned in the same order that the channels are specified in the
<channel_list>.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–7
Command Syntax
The order in which channels are specified is also important in the [ROUTe:]
SCAN <channel_list> command. This determines the order in which the relays
will be closed each time a trigger event is detected.
The order in which channels are specified in a <channel_list> is important in the
[ROUTe:]CLOSe <channel_list> command when channels in the same section of
a VX4320 or a VX4330 are specified. A VX4320 can close only one channel in a
section. If a [ROUTe:]CLOSE <channel_list> command specifies more than one
relay in a section of a VX4320, the last channel in the <channel_list> will be
closed.
For example, the command
close (@m2(1!1,2!1))
will close channel 2 of section 1 of the VX4320.
A VX4330 can close only one channel in a group of joined sections that have
been specified in a [ROUTe:]CLOSe:MODe SCAN,<module_name>,<section_list> command. If more than one channel in such a group of sections is
specified in a [ROUTe:]CLOSe <channel_list> command, the last channel
specified will be closed. For example, the commands
route:configure:join m2,(1:6)
route:close:mode scan,m2,(1:6)
join the commons of all six sections of the VX4330 Module and set the mode of
the [ROUTe]:CLOSE <channel_list> to scan mode for all six sections of the
VX4330.
The command
route:close (@m2(1!1,1!6))
will then result in channel 1 of section 6 being closed and all other channels on
the module being opened.
output queue The Output queue of the Option 01 VXI Interface is used to return
replies to queries received by the interface. Bit 4 (the MAV bit) of the Status
Byte register is set to indicate that this queue is not empty. The DOR bit in the
VXI Response register is also set to indicate that this queue is not empty. The
commander of the Option 01 VXI Interface monitors the DOR bit to determine
when it may read a message from the Output queue.
<section_list>. One or more <nr1> fields separated by comma (,) or colon (:)
characters and enclosed in left and right parentheses. A <section_list> is used to
specify the sections of a relay module to be acted upon by a [ROUTe:]CONFig-
3–8
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Syntax
ure or [ROUTe:]CLOSe:MODE command. The following are examples of valid
<section_list>s.
For commands directed to a VX4330 which has six scanner sections:
<section_list>
Sections Specified
Sections 1 through 6
Sections 1, 2 and 3
Sections 1 through 3 and 5 and 6
Same as previous example
Section 3
For commands directed to a VX4372 or VX4374 which has two scanner
sections:
<section_list>
Sections Specified
Section 1
Sections 1 and 2
Sections 1 and 2
error/event queue. When the command parser detects a syntax error or data range
error, it places an error message describing the error in the Error/Event queue.
Bit 2 of the Status Byte Register is set to indicate that this queue is not empty.
Bit 5 of the Standard Event Status Register (the Command Error bit) is set if the
parser detects a syntax error. Bit 4 of the Standard Event Status register (the
Execution Error bit) is set if the parser detects a numeric argument that is out of
range. When a SYSTem:ERRor? query is received, an error message is dequeued
from the Error/Event queue and placed in the Output queue.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–9
Command Syntax
3–10
VX4380 256-Crosspoint Relay Matrix Module User Manual
Functional Command Groups
This section lists the VX4380 system and module commands.
System Commands
The following low-level commands are typically sent by the module’s commander, and are transparent to the user of the module. (An exception is the Read STB
command, which is sent whenever a Serial Poll on an IEEE-488 system is
performed.) Most commanders or Slot 0 devices have specific ASCII commands
that cause the commander to send one of these low-level commands to a
specified instrument. Refer to the operating manual of the commander or Slot 0
device for information on these commands.
Command
Effect
Begin Normal Operation
The module begins operation if it has not already done so.
Byte Available
Transfers module commands to this module.
Byte Request
Requests the module to return a byte of data from the output
queue.
Clear
The module clears its VXIbus interface and any pending
commands. Current module operations are unaffected.
Clear Lock
Clears the Lock bit of the Response register.
Read Protocol
The module returns its protocol to its commander.
Read STB
The module returns its VXI status byte to its commander.
Set Lock
Set the Lock bit of the Response register.
Trigger
Close the next relay in a scan list that has been defined by a
ROUTe:SCAN <channel_list> command. A VXI Trigger
command is enabled as a trigger source by a ROUTe:SEQuence:SOURce BUS command.
Module Commands
A summary of the VX4380-specific and IEEE-488.2 Common Commands is
listed in Tables 3–1 and 3–2 below. The next section, Command Descriptions,
includes detailed descriptions of each command. Appendix C: Examples shows
examples of command usage.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–11
Functional Command Groups
Table 3–1: Summary of VX4380-Specific SCPI Commands
Subsystem Command
Functions Controlled
ABORt
Place initiated scan in the idle state
CLOSe
Close specified relays; DWELl
CONFigure
Configuration: DISJoin, JOIN
ID?
Return model numbers of modules controlled by the Option 01
INITiate
Place trigger subsystem in armed state: IMMediate,
CONTinuous
MODule
Module name functions: DEFine, CATalog?, DELete
OPEN
Open specified relays: ALL, DWELl
OUTPut
Enable or disable selected VXI TTL trigger
PFAil
Specify state of latching relays on powerfail
SCAN
Define a list of relay closures to scan through
STATus
Status register functions: OPERation, QUESstionable
SYSTem
System-level functions: ERRor?, PRESet, VERSion?
TRIGger
Scan list functions: COUNt, DELay, IMMediate, SOURce
Table 3–2: Summary of IEEE-488.2 Common Commands
3–12
Command/Syntax
Description
Clear Status
*CLS
Clears the SCPI and IEEE 488.2 event registers and
the SCPI error/event queue, and the output queue.
Standard Event Status Enable
*ESE <NRf>
Sets the contents of the Standard Event Status Enable
register.
Standard Event Status Enable Query
*ESE?
Returns the current value of the Standard Event
Status Enable register in <nr1> format.
Standard Event Status Register Query
*ESR?
Returns the current value of the Standard Event
Status register in <nr1> format, then set the contents
of this register to 0.
Identification Query
*IDN?
Returns an ASCII string in the output queue which
identifies the board.
Operation Complete
*OPC
Sets bit 0 (the Operation Complete bit) of the
Standard Event Status register when all pending
device operations have been completed.
Operation Complete Query
*OPC?
Places the ASCII character 1 in the output queue
when all pending device operations have been
completed.
Reset*
*RST
The Option 01 VXI interface is placed in its power-up
state with some exceptions.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Functional Command Groups
Table 3–2: Summary of IEEE-488.2 Common Commands (Cont.)
Command/Syntax
Description
Service Request Enable
*SRE <NRf>
Sets the contents of the Service Request Enable
register.
Service Request Enable Query
*SRE?
Returns the current value of the Service Request
Enable register in <nr1> format.
Read Status Byte Query
*STB?
Returns the current value of the Status Byte register in
<nr1> format.
Trigger
*TRG
Equivalent to a VXI Trigger command.
Self-Test Query
*TST?
Performs a self test of the Option 01 VXI Interface
daughter board and any relay modules under its
control. Place a “0” or “1” into the output queue to
indicate whether the self test passed or failed.
Wait-to-Continue
*WAI
Does not execute any further commands or queries
until all pending operations have been completed.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–13
Functional Command Groups
3–14
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
This section lists the VX4380-specific SCPI commands and queries in alphabetic
order. The IEEE-488.2 Common Commands are listed in the next section. A
summary listing of the SCPI command set for the Option 01 is as follows:
ABORt
[ROUTe:]CLOSe <channel_list>
[ROUTe:]CLOSe:DWELl <module_name>,<nrf>
[ROUTe:]ID?
INITiate:CONTinuous
INITiate[:IMMediate]
[ROUTe:]MODule[:DEFine] <module_name>,<nrf>
[ROUTe:]MODule:CATalog?
[ROUTe:]MODule:DELete[:NAME] <module_name>
[ROUTe:]MODule:DELete:ALL
[ROUTe:]OPEN <channel_list>
[ROUTe:]OPEN:ALL [module_name]
[ROUTe:]OPEN:DWELl <module_name>,<nrf>
OUTPut:TTLTrg<n>[:STATe] ON | OFF | <nrf>
[ROUTe:]PFAil <action_at_powerfail>
[ROUTe:]SCAN <channel_list>
STATus:OPERation:CONDition?
STATus:OPERation:ENABle
STATus:OPERation[:EVENt?]
STATus:QUEStionable:CONDition?
STATus:QUEStionable:ENABle
STATus:QUEStionable[:EVENt?]
SYSTem:ERRor?
SYSTem:PRESet
SYSTem:VERSion?
TRIGger[:SEQuence]:COUNt
TRIGger[:SEQuence]:DELay
TRIGger[:SEQuence]:IMMediate
TRIGger[:SEQuence]:SOURce BUS | HOLD | IMMediate | TTLTrg<n>
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–15
Command Descriptions
ABORt
Command Syntax
Query Syntax
N/A
*RST Value
N/A
Limits
N/A
Related Commands
Description
Examples
3–16
ROUTe:SCAN,
INITiate[:IMMediate],
TRIGger[:SEQuence][:SOURce],
TRIGger[:SEQuence][:IMMediate]
TRIGger[:SEQuence][:COUNt]
TRIGger[:SEQuence][:DELay]
This comand places an initiated scan sequence in the idle state.
The following example defines a scan sequence of 10 relays. The sequence is
aborted after the third relay in the sequence is closed. In this example, module
names m1 and m2 refer to VX4380 Modules. After a scan sequence is aborted,
triggers are no longer accepted by the Option 01 until another INITiate[:IMMediate] command is received.
Command
Response
Define a scan sequence.
This command disables the following trigger sources: VXI TTL
triggers, VXI Trigger commands, *TRG command, and IMMediate triggers. The TRIGger[:SEQuence][:IMMediate] command,
however, overrides this command. It triggers the module and
skips the delay specified in a previously issued TRIGger
[:SEQuence]:DELay command.
Initiate the scan sequence.
Close the first relay in the sequence.
Open the first relay and close the second relay in the sequence.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Command
Response
Open the second relay and close the third relay in the sequence.
Abort the scan sequence.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–17
Command Descriptions
CLOSe
Command Syntax
Query Syntax
Query Response
*RST Value
Limits
"#
"#
Indicates which relays are closed.
All relays on all modules are set to the open position.
The syntax of a <channel_list> is described by the following diagram:
!
"#
$
!
A module_name is an ASCII string that has been associated with a relay module
in a [ROUTe:]MODule[:DEFine] command. A channel_range may consist of a
single <channel_spec> or a range of <channel_spec>s. A range of <channel_spec>s consists of two <channel_specs> separated by a colon (:) character.
One, two and three dimensional <channel_spec>s are supported for the VX4380.
A three dimensional <channel_spec> consists of three ASCII-encoded decimal
integers separated by exclamation point characters (!). The first integer specifies
a row, the second a column, and the third a section of the VX4380. For example,
<channel_spec> 2!3!4 specifies the relay that joins row 2 to column 3 in section
4 of the VX4380.
Two dimensional <channel_spec>s consist of two ASCII-encoded decimal
integers separated by an exclamation point character. The first integer specifies a
row and the second specifies a column. When a two dimensional <channel_spec> is issued, the section number defaults to 1. For example, <channel_spec> 4!15 specifies the relay that joins row 4 to column 15 in section 1.
3–18
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Related Commands
[ROUTe:]OPEN <channel_list>
[ROUTe:]MODule:DEFine
[ROUTE:]CLOSE:DWELl
OUTPut:TTLTrg<n>[:STATe]
A one dimensional <channel_spec> consists of a single ASCII-encoded decimal
integer. The value of a one dimensional <channel_spec> can be determined from
a three dimensional <channel_spec> by using the following formula:
((section - 1) × 64) + ((row - 1) × 16) + column
where variables “section”, “row”, and “column” are section, row and column
numbers specified in a three dimensional <channel_spec>.
For example, the channel spec 3!10!2 specifies the relay that connects row 3 to
column 10 in section 2. The equivalent one dimensional <channel_spec> is equal
to ((2–1) × 64) + ((3–1) × 16) + 10 = 106.
Description
This command closes the relays specified in the <channel_list> portion of this
command. After these relays are closed, a delay specified in a previously issued
[ROUTe:]CLOSe:DWELl command is generated. This command is used to
assign a close delay to each module controlled by an Option 01 daughter board.
If more than one module is specified in the <channel_list> argument of the
[ROUTe:]CLOSe command, the longest dwell time assigned to any of the
specified modules is used. After this delay, VXI TTL triggers that have been
enabled by a previously issued OUTPut:TTLTRG<n>:STATE command are
pulsed low for 3 sec.
Examples
In this example, the Option 01 is installed on a VX4380 Module. Two additional
VX4380 Modules are installed in consecutive slots to the right of the first
VX4380. The default module names for these three modules are m1, m2, and
m3. These module names may be altered with the [ROUTe:]MODule[:DEFine]
command.
Command
Response
route:close:dwell
m1,.1
Assign a close dwell time of 0.1 seconds to the first VX4380.
route:close:dwell
m2,.2
Assign a close dwell time of 0.2 seconds to the second
VX4380.
route:close:dwell
m3,.5
Assign a close dwell time of 0.5 seconds to the third VX4380.
output:ttltrg1:State
on
Enable VXI TTL trigger 1.
output:ttltrg4:state
on
Enable VXI TTL trigger 4.
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
Command Syntax
Command
Response
route:close
(@m1(1:10))
Close the relays that connect row 1 to columns 1 through 10 in
section 1 of the first VX4380, wait 0.1 seconds then pulse VXI
TTL triggers 1 and 4 low for 3 sec.
route:close
(@m2(2!9!3,1!16))
Close the relay that connects row 2 to column 9 in section 3
and the relay that connects row 1 to column 16 of section 1 of
the second VX4380. Wait 0.2 seconds, then pulse VXI TTL
triggers 1 and 4 low for 3 sec.
output:ttltrg4:State
off
Disable VXI TTL trigger 4.
close
(@m1(1!1!2),m2(1!1!2),
m3(1!1!2))
Close the relay that connects row 1 to column 1 in section 2 of
each of the VX4380 Modules, wait 0.5 seconds, then pulse VXI
TTL trigger 1 low for 3 sec.
[ROUTe:]CLOSe
:DWELl<module_name>,<nrf>
Query Syntax
*RST Value
Limits
Related Commands
Description
Examples
3–20
N/A
The close dwell time of all modules is set to 0 seconds.
The value of the time specified in this command must be between 0 and 6.5535
seconds.
[ROUTE:]CLOSe
[ROUTe:]SCAN
OUTPut:TTLTrg<n>[:STATE]
Set the time to wait after closing a relay before proceeding and pulsing any
enabled VXI TTL trigger signals.
In this example the Option 01 is installed on a VX4380 Module.
Command
Response
output:ttltrg1:state
on
Enable VXI TTL trigger 1.
route:close:dwell
m1,.25
Set the close dwell time for the VX4380 to 0.25 seconds.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Command
Response
route:open:dwell
m1,0.5
Set the open dwell time for the VX4380 to 0.5 seconds.
route:close
(@m1(1!3:10!3))
Close relays 1 through 10 in section 3 of the VX4380, wait
0.25 seconds, then pulse VXI TTL trigger 1.
route:scan
(@m1(1!6:20!6))
Define a scan list consisting of relays 1 through 20 in section 6
of the VX4380.
route:close
(@m1(1!1!3:4!1!3))
Close the relays that connect rows 1 through 4 to column 1 in
section 3 of the VX4380, wait 0.25 seconds, then pulse VXI
TTL trigger 1.
scan
(@m1(1!1!1:4!16!1,1!1!
2))
Define a scan list consisting of all relays in section 1 and the
relay that joins row 1 to column 1 in section 2. The relays in
section 1 are specified in the following order:
1!1!1, 1!2!1, 1!3!1, ...,
1!16!1,2!1!1, 2!2!1, 2!3!1, ...,
2!16!1,3!1!1, 3!2!1, 3!3!1, ...,
3!16!1,4!1!1, 4!2!1, 4!3!1, ...,
4!16!1
Note that this scan list can be specified using one dimensional
<channel_spec>s as:
scan (@m1(1:65))
After this sequence, each time the VXI TTL trigger 2 is pulsed low, the
following sequence of events occurs:
1. One second delay. This is the delay specified in the trigger:Sequence:delay
command.
2. The current relay in the scan list is opened.
3. 0.5 second delay. This is the delay specified in the route:open:dwell
command.
4. Close the next relay in the scan list.
5. 0.25 second delay. This is the delay specified in the route:close:dwell
command.
6. Pulse VXI TTL trigger 1 low for 3 sec.
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
ID?
Command Syntax
*RST Value
N/A
Limits
N/A
Related Commands
3–22
[ROUTe:]MODule:CATalog?
Description
This query returns a list of the model numbers of the modules controlled by the
Option 01. The first model number returned is that of the module that the Option
01 is installed on. Subsequent model numbers are those of modules in consecutive slots to the right of the first module.
Examples
In these examples the Option 01 is installed on a VX4350 Module. A VX4380,
VX4380, and VX4320 are installed in consecutive slots to the right of the slot
containing the VX4350. The default module names for the VX4350, VX4380,
VX4380 and VX4320 in this configuration are m1, m2, m3, and m4 respectively.
These module names may be altered with the [ROUTe:]MODule:DEFine command.
Command
Response
" %$
VX4350, VX4380, VX4380, VX4320
" %$ %$ “M1”, “M2”, “M3”, “M4”
" %$ # Close relay number 1 on the VX4350.
" %$ ! Open all relays on the VX4380.
" %$ # Close relay number 1 in section 6 of the VX4380
" %$ #
Close relay number 3 in all eight sections of the VX4320.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
INITiate
Command Syntax
INITiate
[:IMMediate]
Query Syntax
N/A
Query Response
N/A
*RST Value
Related Commands
Description
Examples
The trigger subsystem is in the idle state.
ABORt
ROUTe:SCAN
TRIGger[:SEQuence][:SOURce]
TRIGger[:SEQuence][:IMMediate]
TRIGger[:SEQuence][:COUNt]
TRIGger[:SEQuence][:DELay]
This command places the trigger subsystem in the armed state. In this state, a
trigger event enabled by the TRIGger[:SEQuence][:SOURce] command closes
the next relay in a scan sequence, after opening the previous relay in the
sequence. After a sufficient number of triggers have been received to cycle
through a scan list the number of times specified in a TRIGger:[SEQuence]
:COUNt command, the trigger subsystem is placed in the idle state. In this state,
triggers are ignored.
In this example, module names “m1” and “m2” have been assigned to VX4380
Modules.
Command
Response
route:scan
(@m1(1!1!1),
m2(1!1!1,1!1!2))
Define a scan list consisting of 3 relays.
trigger:sequence:
count 1
Define the number of times to sequence through the scan list
before setting the state of the trigger subsystem back to the
idle state.
initiate:immediate
Initiate the scan sequence.
trig
Close the first relay in the sequence.
trig
Open the first relay and close the second relay in the
sequence.
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
Command Syntax
Command
Response
trig
Open the second relay and close the third relay in the
sequence.
trig
Open the third relay in the sequence. Place the trigger
subsystem in the idle state.
INITiate
:CONTinuous
Query Syntax
*RST Value
Related Commands
Description
Examples
3–24
N/A
The trigger subsystem is in the idle state.
ABORt
ROUTe:SCAN
TRIGger[:SEQuence][:SOURce]
TRIGger[:SEQuence][:IMMediate]
[:SEQuence][:DELay]
If a scan list has been defined by a [ROUTe:]SCAN command, this command
places the trigger subsystem in the armed state. In this state, a trigger event
enabled by the TRIGger[:SEQuence]:SOURce command opens the currently
closed channel in a scan list and closes the next channel in the list. Triggers
continue to be recognized until an ABORt command is received, which returns
the trigger subsystem to the IDLE state.
In this example, it is assumed that the Option 01 daughter board is installed on a
VX4380 Module, and that the default module name “m1” is in effect.
Command
Response
scan (@m1(1:64))
Define a scan list consisting of all relays in section 1 of the
VX4380 Module.
trigger:Sequence:
count 2
Set the number of times to sequence through a scan list (when
an INITiate[:IMMediate] command is received) to 2.
trigger:sequence:
source hold
Disable all trigger sources.
initiate:continuous
Place the trigger subsystem in the arm state.
trigger:seq:imm
Override the hold placed on triggers. Close channel 1 on the
VX4380.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Command
Response
Override the hold placed on triggers. Open channel 1, then
close channel 2 on the VX4380.
Remove the hold placed on triggers. Set the trigger source to
immediate. This causes sequencing of the scan list indefinitely
or until an ABORt command is received.
Return the trigger subsystem to the idle state. Open the
currently closed relay in the scan list.
Place the trigger subsystem in the arm state, sequence through
the scan list twice, then return the trigger subsystem to the idle
state.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–25
Command Descriptions
MODule
Command Syntax
&
! "&! !#
Query Syntax
&
! "&! Query Response
*RST Value
See examples.
Default module names are assigned as follows:
The module that has a Option 01 VXI Interface daughter board installed is
assigned module name “M1”.
Modules without the Option 01 VXI Interface daughter board in consecutive
slots to the right of module “M1” are assigned module names “M2”, “M3”, ...,
“M11”.
Limits
Related Commands
Description
Examples
3–26
A module name may consist of up to 12 characters. The name must start with a
letter and may consist of alphanumeric characters, underscores, and digits.
[ROUTe]:MODule:DELete[:NAME]
[ROUTe]:MODule:DELete[:ALL]
[ROUTe:]MODule:CATalog?
This command assigns a module name to a relay switching module. This name is
used to identify the module in channel lists in [ROUTe:]OPEN,
[ROUTe:]CLOSe, and [ROUTe:]SCAN commands.
In these examples the Option 01 is installed on a VX4350 Module. A VX4380
and VX4380 are installed in consecutive slots to the right of the slot containing
the VX4350.
Command
Response
#"&% "&!
%#'
Assign module name “matrix” to the VX4380.
"$ %#'
Connect row 2 to column 3 in section 4 of the VX4380.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Command Syntax
Command
Response
route:module:define?
matrix
2
mod?matrix
2
[ROUTe:]MODule
:CATalog?
*RST Value
N/A
Limits
N/A
Related Commands
Description
Examples
[ROUTe]:MODule:DEFine[:NAME]
[ROUTe]:MODule:DELete[:NAME],
[ROUTe]:MODule:DELete[:ALL]
This command returns a list of defined module names.
In these examples the Option 01 is installed on a VX4350 Module. A VX4380
and VX4380 are installed in consecutive slots to the right of the slot containing
the VX4350.
Command
Response
route:module:catalog?
“M1”, “M2”, “M3”
route:module:delete m1
Delete module name “M1”
route:module:catalog?
“M2”, “M3”
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Command Descriptions
Command Syntax
Query Syntax
N/A
*RST Value
N/A
Limits
N/A
Related Commands
Description
Examples
Command Syntax
[ROUTe]:MODule:DEFine[:NAME]
[ROUTe]:MODule:CATalog?
[ROUTe:]MODule:DELete[:ALL]
This command deletes a module name definition. After this command is
executed, the specified module name is no longer associated with a relay
module.
Command
Response
“M1”, “M2”, “M3”
Delete module name “M1”
“M2”, “M3”
3–28
Query Syntax
N/A
*RST Value
N/A
Limits
N/A
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Related Commands
Description
Examples
[ROUTe]:MODule:DEFine[:NAME]
[ROUTe]:MODule:CATalog?
[ROUTe:]MODule:DELete[:NAME]
This command will delete all module name definitions.
Command
Response
“M1”, “M2”, “M3”
Delete all module names
“”
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
OPEN
Command Syntax
Query Syntax
Query Response
*RST Value
Limits
"#
"#
See examples.
All relays on all modules are set to the open position.
The syntax of a <channel_list> is described by the following diagram:
!
"#
$
!
A module_name is an ASCII string that has been associated with a relay module
in a [ROUTe:]MODule[:DEFine] command. A channel_range may consist of a
single <channel_spec> or a range of <channel_spec>s. A range of <channel_spec>s consists of two <channel_specs> separated by a colon (:) character.
One, two and three dimensional <channel_spec>s are supported for the VX4380.
A three dimensional <channel_spec> consists of three ASCII-encoded decimal
integers separated by exclamation point characters (!). The first integer specifies
a row, the second a column, and the third a section of the VX4380. For example,
<channel_spec> 2!3!4 specifies the relay that joins row 2 to column 3 in section
4 of the VX4380.
Two dimensional <channel_spec>s consist of two ASCII-encoded decimal
integers separated by an exclamation point character. The first integer specifies a
row and the second specifies a column. When a two dimensional <channel_spec> is issued, the section number defaults to 1. For example, <channel_spec> 4!15 specifies the relay that joins row 4 to column 15 in section 1.
3–30
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
A one dimensional <channel_spec> consists of a single ASCII-encoded decimal
integer. The value of a one dimensional <channel_spec> can be determined from
a three dimensional <channel_spec> by using the following formula:
((section - 1) × 64) + ((row - 1) × 16) + column
where variables “section”, “row”, and “column” are section, row and column
numbers specified in a three dimensional <channel_spec>.
For example, the channel spec 3!10!2 specifies the relay that connects row 3 to
column 10 in section 2. The equivalent one dimensional <channel_spec> is equal
to ((2–1) × 64) + ((3–1) × 16) + 10 = 106.
Related Commands
Description
Examples
[ROUTe:]CLOSe <channel_list>,
[ROUTe:]MODule:DEFine,
[ROUTE:]OPEN:DWELl
This command opens the relays specified in the <channel_list> portion of this
command.
In this example, the Option 01 is installed on a VX4380 Module. Two additional
VX4380 Modules are installed in consecutive slots to the right of the first
VX4380. The default module names for these three modules are m1, m2, and
m3. These module names may be altered with the [ROUTe:]MODule[:DEFine]
command.
Command
Response
route:open:dwell m1,.1
Assign a open dwell time of 0.1 seconds to the first VX4380.
route:open:dwell m2,.2
Assign a open dwell time of 0.2 seconds to the second
VX4380.
route:open:dwell m3,.5
Assign a open dwell time of 0.5 seconds to the third VX4380.
route:open (@m1(1:10))
Open the relays that connect row 1 to columns 1 through 10 in
section 1 of the first VX4380, then wait 0.1 seconds.
route:open
(@m2(2!9!3,1!16))
Open the relay that connects row 2 to column 9 in section 3
and the relay that connects row 1 to column 16 of section 1 of
the second VX4380, then wait 0.2 seconds.
open (@m1(1!1!2),
m2(1!1!2),m3(1!1!2))
Open the relay that connects row 1 to column 1 in section 2 of
each of the VX4380 modules, then wait 0.5 seconds.
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
Command
Response
#$" !
Open all relays in section 1 of the first VX4380, then wait 0.1
seconds.
#$" !
111111111111111111111111111111111
1111111111111111111111111111111
This response indicates that all relays in section 1 of the first
VX4380 are open.
Command Syntax
!#' "!
Query Syntax
*RST Value
Limits
Related Commands
Description
Examples
N/A
All relays on all modules are set to the open position.
N/A
[ROUTe:]CLOSe,
[ROUTe:]MODule:DEFine
If a module name is not specified in this command, open all relays on all
modules controlled by the Option 01. If a module name is specified, open all
relays on the specified module only. In either case do not change the state of the
configuration relays on VX4380 Modules.
Command
Response
Open all relays on all modules controlled by the Option 01. Do
not change the state of the configuration relays on VX4380
Modules.
%#'&#$"
Same as the first example.
%#'&#$"
Command Syntax
$
Open all relays on the module that has been assigned module
name “gp”. See the [ROUTe:]MODule:DEFine command.
!#' "!
"%
Query Syntax
3–32
N/A
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
*RST Value
Limits
Related Commands
Description
Examples
The open dwell time of all modules is set to 0 seconds.
The value of the time specified in this command must be between 0 and
6.5535 seconds.
[ROUTE:]OPEN,
[ROUTe:]SCAN
This command sets the time to wait after opening a relay before proceeding.
In this example the Option 01 is installed on a VX4380 Module.
Command
Response
output:ttltrg1:state
on
Enable VXI TTL trigger 1.
route:close:dwell
m1,.25
Set the close dwell time for the VX4380 to .25 seconds.
route:open:dwell
m1,0.5
Set the open dwell time for the VX4380 to 0.5 seconds.
scan
(@m1(1!1!1:4!16!1,
1!1!2))
Define a scan list consisting of all relays in section 1 and the
relay that joins row 1 to column 1 in section 2. The relays in
section 1 are specified in the following order:
1!1!1, 1!2!1, 1!3!1, ..., 1!16!1,
2!1!1, 2!2!1, 2!3!1, ..., 2!16!1,
3!1!1, 3!2!1, 3!3!1, ..., 3!16!1,
4!1!1, 4!2!1, 4!3!1, ..., 4!16!1
Note that this scan list can also be specified using one
dimensional <channel_spec>s as
:route:Scan (@m1(1:65))
trigger:Sequence:
source:ttltrg2
Define VXI TTL trigger 2 as the trigger source for the defined
scan list.
trigger:sequence:
delay 1
Set the trigger delay time to 1 second.
initiate:immediate
Initiate the scan sequence.
After this sequence, each time the VXI TTL trigger 2 is pulsed low, the
following sequence of events occurs:
1. One second delay. This is the delay specified in the trigger:Sequence:delay
command.
2. The current relay in the scan list is opened.
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
3. 0.5 second delay. This is the delay specified in the route:open:dwell
command.
4. Close the next relay in the scan list.
5. 0.25 second delay. This is the delay specified in the route:close:dwell
command.
6. Pulse VXI TTL trigger 1 low for 3 sec.
3–34
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
OUTPut
Command Syntax
! ! Query Syntax
Query Response
*RST Value
Related Commands
Description
Examples
Indicates whether a VXI TTL trigger is enabled.
ROUTe:CLOSe
ROUTe:SCAN
One or more VXI TTL triggers may be enabled. Triggers that are enabled are
pulsed low for 3 sec after a relay is closed by the Option 01 after a time
specified by the ROUTe:CLOSe:DWELl command.
Command
Response
Enable driving VXI TTL trigger 1.
Disable driving VXI TTL trigger 2.
Enable driving VXI TTL trigger 7.
1
This response indicates that VXI TTL trigger 4 is enabled.
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
PFAil
Command Syntax
Query Syntax
*RST Value
[ROUTe:]PFAil <action_at_powerfail>
N/A
All relays on all modules are opened when power is removed from the VXI
chassis.
Limits
N/A
Related Commands
N/A
Description
This command specifies the state that all latching relays on all modules
controlled by the Option 01 are to be placed in when power is removed from the
VXI chassis containing the modules. <action_at_powerfail> must be OPEN or
SAME. If OPEN is specified, all latching relays are opened at powerfail. If
SAME is specified, all latching relays are left in their current state at powerfail.
NOTE. VXI chassis +5 V power is maintained for 4 milliseconds after ACFAIL is
asserted, in compliance with VXI Specifications. This allows for orderly system
shutdown and implementation of the PFAil OPEN option.
Examples
3–36
Command
Response
route:pfail same
Leave all latching relays in their current state at powerfail.
route:pfail open
Open all latching relays at powerfail.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
SCAN
Command Syntax
Query Syntax
*RST Value
Limits
#$
#$!#$#
N/A
No scan list is defined.
The syntax of a <channel_list> is described by the following diagram:
" #$
!% " A module_name is an ASCII string that has been associated with a relay module
in a [ROUTe:]MODule[:DEFine] command. A channel_range may consist of a
single <channel_spec> or a range of <channel_spec>s. A range of <channel_spec>s consists of two <channel_specs> separated by a colon (:) character.
One, two and three dimensional <channel_spec>s are supported for the VX4380.
A three dimensional <channel_spec> consists of three ASCII-encoded decimal
integers separated by exclamation point characters (!). The first integer specifies
a row, the second a column, and the third a section of the VX4380. For example,
<channel_spec> 2!3!4 specifies the relay that joins row 2 to column 3 in section
4 of the VX4380.
Two dimensional <channel_spec>s consist of two ASCII-encoded decimal
integers separated by an exclamation point character. The first integer specifies a
row and the second specifies a column. When a two dimensional <channel_spec> is issued, the section number defaults to 1. For example, <channel_spec> 4!15 specifies the relay that joins row 4 to column 15 in section 1.
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Command Descriptions
A one dimensional <channel_spec> consists of a single ASCII-encoded decimal
integer. The value of a one dimensional <channel_spec> can be determined from
a three dimensional <channel_spec> by using the following formula:
((section - 1) × 64) + ((row - 1) × 16) + column
where variables “section”, “row”, and “column” are section, row and column
numbers specified in a three dimensional <channel_spec>.
For example, the channel spec 3!10!2 specifies the relay that connects row 3 to
column 10 in section 2. The equivalent one dimensional <channel_spec> is equal
to ((2–1) × 64) + ((3–1) × 16) + 10 = 106.
The syntax of a <list_of_lists> is supported on the VX4350 and VX4380
modules and is described by the following diagram:
<list_of_lists>
,
,
,
(
@
<module_name>
(
<channel_range>
)
)
Each <channel_list> is identified by the @ character and represents a single
location in the scan sequence. The syntax contains a list of channels that are
operated simultaneously when the single location in the scan sequence is
reached.
A maximum of eight channels may be specified in each <channel_range>.
Related Commands
Description
3–38
ABORT
TRIGger[:SEQuence]:SOURce,
TRIGger[:SEQuence]:COUNt,
TRIGger[:SEQuence]:DELay,
TRIGger[:SEQuence]:IMMediate,
TRIGger[:SEQuence]:COUNt,
INITiate:CONTinuous
INITiate[:IMMediate],
[ROUTe:]CLOSe:DWELl
[ROUTe:]OPEN:DWELl
This command defines a list of relay closures to sequence through. This list is
called a scan list. When the ROUTe:SCAN <channel_list> command is received,
all relays in this list are opened. In addition to defining a scan list, a trigger
source must be specified using the TRIGger[:SEQuence]:SOURce command.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Trigger events are not recognized until triggers are armed by a INITiate[:IMMediate] or INITiate:CONTinuous command.
When the first trigger event is detected, the first relay in the scan list is closed.
When the second trigger event is detected, the first relay is opened and the
second relay is closed. When the nth trigger event is detected, the (n–1)th relay is
opened and the nth relay is closed. The act of opening the (n–1)th relay and
closing the nth relay is called sequencing the scan list. At any given time after
the first trigger event is detected, only one relay in the scan list is closed.
The TRIGger[:SEQuence]:COUNt command may optionally be used to specify
the number of times to sequence through the entire scan list. The TRIGger[:SEQuence]:DELay, [ROUTe:]CLOSe:DWELl, and [ROUTe:]OPEN:DWELl
commands may optionally be used to specify the time to wait after a trigger
event is detected, a relay is closed or a relay is opened. A TRIGger[:SEQuence]:IMMediate command causes the scan list to be sequenced without the
delay specified by a previously issued TRIGger[:SEQuence]:DELay command.
Examples
In these examples the Option 01 is installed on a VX4350 Module. A VX4380
and VX4380 are installed in consecutive slots to the right of the slot containing
the VX4350.
Command
Response
!$#$
Assign module name “gp” to the VX4350.
!$#$
#!&
Assign module name “matrix” to the VX4380.
!$#$
"
Assign module name “scan” to the VX4380.
!$#" #!&
"
Define a scan list consisting of relays 1 through 64 on the
VX4350, relays at row 1, column 1 of section 1 and row 2,
column 10 of section 3 of the VX4380 and relays 1 through 20
of section 1 of the VX4380.
#!!" $
"$! #
Define a trigger source of “immediate”. This means to
sequence through the scan list without waiting for a trigger
event.
#!!" $$#
Sequence through the entire scan list 5 times.
!$#"%
Wait 0.5 seconds after closing a relay on the VX4350.
###
Begin sequencing through the scan list.
Set the Operation Complete bit of the Standard Event Status
register after sequencing through the scan list five times.
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Command Descriptions
Command
Response
! Define a scan list of three entries on the VX4350, each entry
consisting of eight relays to be closed simultaneously.
Begin sequencing through the scan list.
Set the Operation Complete bit of the Standard Event Status
register after sequencing through the scan list five times.
! "
"
"
Define a scan list of three entries. Each entry consists of a
single relay on the VX4350 and a single relay on each of the
VX4380s to be closed simultaneously.
3–40
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
STATus
Command Syntax
*RST Value
0
Limits
N/A
Related Commands
N/A
Description
This query returns the contents of the SCPI Status Operation Condition register.
For the Option 01, the value of this register is always equal to 0.
Examples
Command Syntax
Command
Response
status:operation:
condition?
00000
Query Syntax
*RST Value
0
Limits
N/A
Related Commands
N/A
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Command Descriptions
Description
Examples
Command Syntax
This command sets the contents of the SCPI Status Operation Event Enable
register.
Command
Response
status:operation:
enable 1
No response
stat:oper:enab?
00001
STATus
:OPERation
[:EVENt?]
*RST Value
0
Limits
N/A
Related Commands
N/A
Description
Examples
Command Syntax
This query returns the contents of the SCPI Status Operation Event register. For
the Option 01, the value of this register is always equal to 0.
Command
Response
status:operation:
event?
00000
STATus
:QUEStionable
:CONDition?
*RST Value
3–42
0
Limits
N/A
Related Commands
N/A
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Description
Examples
Command Syntax
This query returns the contents of the SCPI Status Questionable Condition
register. For the Option 01, the value of this register is always equal to 0.
Command
Response
00000
Query Syntax
Query Response
*RST Value
Indicates whether the Status Operation Event is enabled.
0
Limits
N/A
Related Commands
N/A
Description
Examples
This command sets the contents of the SCPI Status Operation Event Enable
register.
Command
Response
No response
00001
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Command Descriptions
Command Syntax
STATus
:QUEStionable
[:EVENt?]
*RST Value
Limits
N/A
Related Commands
N/A
Description
Examples
3–44
0
This query returns the contents of the SCPI Status Questionable Event register.
For the Option 01, the value of this register is always equal to 0.
Command
Response
status:questionable:
event?
00000
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
SYSTem
Command Syntax
Query Response
Parameter “y” in these error messages represents the local bus address of the
module that the error message applies to. A value of 1 indicates the module
containing the Option 01 daughter board, a value of 2 indicates the module in the
next slot to the right, and so on.
0,“No error”
–102, “Syntax error; 1 dimensional <channel_spec> invalid for VX4380
module”
–102, “Syntax error; 2 dimensional <channel_spec> invalid for VX4350
module”
–102, “Syntax error; 3 dimensional <channel_spec> invalid for VX43xx
module”
–102, “Syntax error; channel dimension mismatch”
–102, “Syntax error; integer field greater than 10 characters”
–102, “Syntax error; Missing module name”
–102, “Syntax error; Module address not specified”
–102, “Syntax error; Module name already defined”
–102, “Syntax error; Module name length greater than 12 characters”
–102, “Syntax error; Non-contiguous section numbers”
–102, “Syntax error; ROUTe:CONFigure command invalid for VX43xx module”
–102, “Syntax error; ROUTe:DISJoin command invalid for VX43xx module”
–102, “Syntax error; ROUTe:JOIN command invalid for VX43xx module”
–102, “Syntax error; ROUTe:MODE command invalid for VX43xx module”
–102, “Syntax error; Undefined module name”
–102, “Syntax error; Unexpected x detected while ...”
–121, “Invalid character in number”
–123, “Exponent too large”
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
–200, “Execution error; Reserved”
–200, “Execution error; Scan list undefined”
–211, “Trigger ignored”
–213, “Init ignored”
–222, “Data out of range; Channel number x on module y”
–222, “Data out of range; Channel number x!x on module y”
–222, “Data out of range; Channel number x!x!x on module y”
–222, “Data out of range; Invalid module address specified”
–222, “Data out of range; Invalid section number”
–222, “Data out of range; Invalid sequence count”
–222, “Data out of range; Invalid trigger delay”
–222, “Data out of range; Invalid VXI TTL Trigger level”
–222, “Data out of range; Maximum value for ESE command is 255”
–222, “Data out of range; Maximum value for SRE command is 255”
–222, “Data out of range; Invalid dwell time specified.”
–223, “Too much data; Channel list array overflow”
–223, “Too much data; Input buffer overflow”
–223, “Too much data; Output buffer full”
–223, “Too much data; Scan list array overflow”
–240, “Hardware error; Shift register verification error – module y”
–240, “Hardware error; Unrecognized module x, y”
–350, “Queue overflow; Error/event queue”
–350, “Queue overflow; Output queue”
*RST Value
Limits
Related Commands
3–46
The Error/Event queue is empty.
N/A
*ESR?,
*STB?
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Description
Examples
Command Syntax
If an error condition is detected by the Option 01, it places an error message
describing the condition in the error/event queue. The SYSTem:ERRor? query
requests the Option 01 to remove the oldest message in the error/event queue and
place it into the output queue. If the error/event queue is empty, a “No error”
message is placed in the output queue.
Command
Response
SYSTEM:ERROR?
0, “No error”
syst:err?
–222, “Data out of range; Invalid section number”
Query Syntax
N/A
*RST Value
N/A
Limits
N/A
Related Commands
Description
ROUTe:OPEN:ALL
All relays on all modules (except VX4320 Modules) are set to the open position.
The PON bit of the Standard Event Status register is not affected by this
command.
Examples
Command Syntax
Command
Response
No response
No response
*RST Value
N/A
Limits
N/A
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
Related Commands
Description
None
This query returns the following ASCII string in the output queue:
“1994.0”
Examples
3–48
Command
Response
“1994.0”
“1994.0”
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
TRIGger
Command Syntax
TRIGger
[:SEQuence]
:COUNt
Query Syntax
*RST Value
Limits
Related Commands
Description
Examples
Command Syntax
N/A
1
The count specified in this command must be between 1 and 65535.
ABORt, ROUTe:SCAN
INITiate:IMMediate
TRIGger[:SEQuence]:SOURce]
TRIGger[:SEQuence]:IMMediate]
TRIGger[:SEQuence]:DELay]
This command specifies the number of times to sequence through an entire scan
sequence.
Define a scan sequence consisting of relays 1 and 2 on relay module “m1” and
relays 1 through 64 on module “m2”.
Command
Response
trigger:sequence:count
2
Define the number of times to sequence through the scan list
before setting the state of the trigger subsystem back to the
idle state.
trigger:sequence:
source immediate
Sequence through the scan list without waiting for a trigger
event after an INITiate[:Immediate] command is received.
initiate:immediate
Initiate the scan sequence. Sequence through the entire scan
list two times.
TRIGger
[:SEQuence]
:DELay
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Command Descriptions
Query Syntax
*RST Value
Limits
Related Commands
Description
Examples
Command Syntax
N/A
0
The time specified in this command must be between 0.001 and 6.5535 seconds.
ABORt, ROUTe:SCAN
TRIGger[:SEQuence]:SOURce
TRIGger[:SEQuence]:IMMediate
This command specifies the time to wait after a trigger event is detected before
sequencing to the next channel in a scan list.
Command
Response
route:scan
(@m1(1,2),m2(1:64))
Define a scan sequence consisting of relays 1 and 2 on relay
module “m1” and relays 1 through 64 on module “m2”.
trigger:sequence:
count 2
Define the number of times to sequence through the scan list
before setting the state of the trigger subsystem back to the
idle state.
trigger:sequence:
delay 0.5
Wait 0.5 seconds after a trigger event is detected before
opening the current relay in a scan list and closing the next
relay in the list.
trigger:sequence:
source ttltrg2
Sequence to the next relay in a scan list when VXI TTL trigger
2 is asserted.
initiate:immediate
Initiate the scan sequence. Sequence through the entire scan
list two times. Wait 0.5 seconds after VXI TTL trigger 2 is
asserted before sequencing to the next relay in the list.
TRIGger
[:SEQuence]
:IMMediate
3–50
Query Syntax
N/A
*RST Value
N/A
Limits
N/A
VX4380 256-Crosspoint Relay Matrix Module User Manual
Command Descriptions
Related Commands
Description
Examples
Command Syntax
ABORt, ROUTe:SCAN
TRIGger[:SEQuence]:SOURce
TRIGger[:SEQuence]:COUNt
TRIGger[:SEQuence]:DELay
Sequence to the next relay in an initiated scan list without waiting for a trigger
event and without waiting the time specified in a TRIGger[:SEQuence]:DELay
command.
Command
Response
route:scan
(@m1(1,2),m2(1:64))
Define a scan sequence consisting of relays 1 and 2 on relay
module “m1” and relays 1 through 64 on module “m2”.
trigger:sequence:
count 2
Define the number of times to sequence through the scan list
before setting the state of the trigger subsystem back to the
idle state.
trigger:sequence:
delay 0.5
Wait 0.5 seconds after a trigger event is detected before
opening the current relay in a scan list and closing the next
relay in the list.
trigger:sequence:
source ttltrg2
Sequence to the next relay in a scan list when VXI TTL trigger
2 is asserted.
initiate:immediate
Initiate the scan sequence. Sequence through the entire scan
list 2 times. Wait 0.5 seconds after VXI TTL trigger 2 is
asserted before sequencing to the next relay in the list.
trigger:sequence:
immediate
Sequence to the next relay in the scan list without waiting for
VXI TTL trigger 2 to be asserted. Do not wait 0.5 seconds to
sequence to the next relay.
TRIGger
[:SEQuence]
:SOURce BUS | HOLD | IMMediate | TTLTrg<n>
Query Syntax
*RST Value
Limits
Related Commands
N/A
IMMediate
N/A
ABORt, ROUTe:SCAN
TRIGger[:SEQuence]:[SOURce]
TRIGger[:SEQuence]:[IMMediate]
VX4380 256-Crosspoint Relay Matrix Module User Manual
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Command Descriptions
TRIGger[:SEQuence]:COUNt
TRIGger[:SEQuence]:DELay
Description
This command selects a trigger source. When a trigger event is detected from an
enabled trigger source, the next relay in an initiated scan sequence is closed after
the current closed relay is opened.
The action of opening the currently closed relay and closing the next relay in a
scan list is called sequencing the scan list.
Specifying BUS in the TRIGger[:SEQuence]:SOURce command enables a
IEEE488.1 Group Execute Trigger command to sequence the scan list.
It is assumed that the commander of the Option 01 is a IEEE488 talker/listener
and that this device converts a IEEE488.1 GET command to a VXI Trigger
command.
Specifying HOLD in the TRIGger[:SEQuence]:SOURce command disables all
trigger sources except the TRIGger[:SEQuence}[:IMMediate] comand.
Specifying IMMediate in the TRIGger[:SEQuence]:SOURce command causes
the Option 01 to sequence through the scan list without waiting for a trigger
event.
Specifying TTLTrg<n> in the TRIGger[:SEQuence]:SOURce command enables
one of eight VXI TTL triggers to act as a trigger source. <n> is a single digit
between 0 and 7.
Examples
3–52
Command
Response
Define a scan sequence consisting of relays 1 and 2 on relay
module “m1” and relays 1 through 64 on module “m2”.
Define the number of times to sequence through the scan list
before setting the state of the trigger subsystem back to the
idle state.
Sequence through the scan list without waiting for a trigger
event after an INITiate[:Immediate] command is received.
Initiate the scan sequence. Sequence through the entire scan
list two times.
VX4380 256-Crosspoint Relay Matrix Module User Manual
IEEE-488.2 Common Commands
This section lists the IEEE-488.2 common commands and queries recognized by
the VX4380.
*CLS
Clear Status. This commands clears the following:
Event Status register (ESR)
Error/Event queue
Output queue
*ESE <NRf>
Event Status Enable (ESE) command. This command defines the mask for
setting the Event Status Summary bit (bit 5) in the Status Byte register (*STB?).
The mask is logically ANDed with the Event Status register (*ESR?) to
determine whether or not to set the Event Status Summary bit. The mask can be
any numeric value from 0 to 255, corresponding to the encoded bits of the ESR
register. A “1” in a bit position enables reporting of the function. A “0” disables
it. The *ESE register is cleared at power-on, or by writing an *ESE 0 command
only. If <mask> is not specified, it defaults to 0.
For example, the command *ESE 37 (hexadecimal 25, binary 00010101) enables
setting the Event Status Summary bit whenever an operation is complete, a query
error is detected, or an execution error is detected.
*ESE?
Event Status Enable (ESE) query. This command returns the value of the Event
Status Enable register as a numeric value from 0 to 255. For example, a value of
32 (hexadecimal 40, binary 00100000) indicates that command error reporting is
enabled.
*ESR?
Event Status Register (ESR) query. This command returns the value of the Event
Status register. The *ESR command is destructively read (that is, read and
cleared). The Event Status Summary bit in the Status Byte (*STB?) is also
cleared by a read of the ESR. The ESR is set to 128 on power-on (bit 7) set. It is
VX4380 256-Crosspoint Relay Matrix Module User Manual
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IEEE-488.2 Common Commands
cleared by an *ESR? or *CLS command only. When converted to a binary
number, the bits of the ESR correspond to:
bit 0 (LSB)
1
2
3
4
5
6
7 (MSB)
Operation Complete
Request Control
Query error
Device Dependent error
Execution error
Command error
User Request
Power On
The Error bits are set whenever the module detects an error. The error values
from –100 to –199 are Command errors. Error values from –200 to –299 are
Execution errors. Error values from –300 to –399 are Device Dependent errors.
Error values from –400 to –499 are Query errors (see the SYSTem:ERRor
command description).
The Request Control and User Request bits are unused, and are always reported
as zeroes.
The Operation Complete bit is set in response to an *OPC command. A 1
indicates that the module has completed all pending commands and queries.
*IDN?
Identification query; This returns a 4-field response. Field 1 is the manufacturer,
field 2 the model, field 3 the serial number, and field 4 contains both the SCPI
and the firmware version levels. For the VX4380, the serial number field is
always a 0. The response syntax is:
where xx indicates the model number of the relay module that the Option 01 is
installed on:
3–54
Value of xx
Model Number
20
VX4320
30
VX4330
50
VX4350
80
VX4380
VX4380 256-Crosspoint Relay Matrix Module User Manual
IEEE-488.2 Common Commands
*OPC
Operation Complete. This command causes the module to set the Operation
Complete bit in the Event Status register (ESR) when all pending commands and
queries are complete.
*OPC?
Operation Complete query. This command causes the module to place a “1” in
the Output queue when all pending commands and queries are complete. All
commands following *OPC are suspended until the pending operations are
complete. The *OPC? command does not affect the OPC bit in the Event Status
register.
*RST
Reset. This command causes the Option 01 to open all relays on all modules
under its control. This command sets the Option 01 Module to its power-on state
with the following exceptions: the Error/Event queue, Output queue, Standard
Event Status Enable register, SCPI Status Operation Event Enable register and
SCPI Status Questionable Event Enable register are not cleared.
The condition of the Option 01 daughter board and the switching modules that it
controls after receipt of a *RST command is as follows:
Contents of the SCPI Status Operation Event register = 0
Contents of the SCPI Status Operation Condition register = 0
Contents of the SCPI Status Questionable Event register = 0
Contents of the SCPI Status Questionable Condition register = 0
All VXI TTL triggers are disabled
Trigger subsystem is in the idle state
Trigger source = IMMediate
Number of times to sequence through an entire scan list = 1
Time in seconds to wait after a trigger event is detected before sequencing to
the Next relay in a scan list = 0
All relays on all modules are set to the open position
No scan list is defined
Default module names are assigned as follows:
The module that has a Option 01 VXI Interface daughter board installed
is assigned module name “M1”.
Modules without the Option 01 VXI Interface daughter board in
consecutive slots to the right of module “M1” are assigned module
names “M2”, “M3”, ..., “M11”.
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IEEE-488.2 Common Commands
All sections on all scanner modules are disjoined
All sections of all VX4330 Modules are set to operate in the mux mode
Close dwell time of all modules is set to 0 seconds
Open dwell time of all modules is set to 0 seconds
All relays on all modules are opened when power is removed from the VXI
chassis
*SRE <mask>
Service Request Enable (SRE) register. This command defines a mask that is
ANDed with the contents of the Status Byte register. If the result of this
operation is non-zero, the Option 01 generates a VXI Request True interrupt.
Bits 0, 1, 3, 6, and 7 of the SRE register are not used. Bits 2, 4, and 5 are set to
enable VXI Request True interrupts to be generated under the conditions listed in
the following table.
Bit No.
Meaning
bit0 (LSB)
Not used
1
Not used
2
The Error/Event queue contains one or more error messages
3
Not used
4
The Output queue contains one or more query responses
5
The contents of the Standard Event Status register ANDed with the
contents of the Standard Event Status Enable register produces a
non-zero result.
6
Not used
7
Not used
*SRE?
Service Request Enable (SRE) query. This command returns the value of the
Service Request Enable register as a numeric value from 0 to 255. Bit 6 is
unused, and is reported as zero.
3–56
VX4380 256-Crosspoint Relay Matrix Module User Manual
IEEE-488.2 Common Commands
*STB?
Status Byte Query. This query returns the value of the Status Byte register as a
numeric value between 0 and 255. The Status Byte register contents (with the
exception of bit 6) are also returned in response to a VXI Read STB command.
Bit 6 is read destructively in response to a VXI Read STB command. Bit 6 is not
read destructively is response to a *STB? query. The Status Byte register is
encoded as follows:
Bit No.
Meaning
bit 0 (lsb)
Not used
bit 1
Not used
bit 2
Set when the Error/Event queue contains one or more error messages.
bit 3
Not used
bit 4
Set when the Output buffer contains one or more query responses.
bit 5
Set when the contents of the Standard Event Status register ANDed
with the contents of the Standard Event Status Enable register
produces a non-zero result.
bit 6
Set when the contents of bits 0 through 5 and bit 7 of the Status Byte
register ANDed with the contents of the Service Request Enable
register produce a non-zero result.
If bit 6 becomes set, the Option 01 will generate a VXI Request True
interrupt on the VME interrupt level selected by its interrupt level select
switch. If bit 6 becomes set and the Status Byte register is read using a
VXI Read STB command, bit 6 will be reported as being set. In
response to subsequent VXI Read STB commands, bit 6 will be
reported as being cleared.
If bit 6 becomes set and the Status Byte register is read using a *STB?
query, bit 6 will be reported as being set. Bit 6 will continue to be
reported as set in reponse to *STB queries until the contents of bits 0
through 5 and bit 7 of the Status Byte register ANDed with the contents
of the Service Request Enable register is equal to 0.
bit 7
Not used.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–57
IEEE-488.2 Common Commands
*TRG
Trigger Command. This command is equivalent to a VXI Trigger command.
This command is valid only after the following commands have been received
by the Option 01:
Command
Description
[ROUTe:]SCAN
<channel_list>
Define a scan list
TRIGger
[:SEQuence]
:SOURce BUS
Select a VXI Trigger command as a trigger source.
INITiate[:IMMediate]
Initiate the scan list. This command places the trigger
subsystem in the “ARM” state. The trigger subsystem remains
in this state until the Option 01 has sequenced through the
entire scan list “n” times, where “n” has been previously
specified in a TRIGger[:SEQuence]:COUNT command. The
trigger subsystem then returns to the IDLE state. The trigger
subsystem also returns to the IDLE state if an ABORt
command is received by the Option 01.
After these commands have been issued, a *TRG command will cause the
Option 01 to take the following actions:
Generate a trigger delay that has previously been specified in a TRIGger
[:SEQuence]:DELay command.
Open the currently closed channel.
Generate the open delay that has previously been specified in a
[ROUTe:]OPEN:DWELl command.
Close the next channel in the scan list.
Generate the close delay that has previously been specified in a
[ROUTe:]CLOSe:DWELl.
Pulse one or more VXI TTL trigger signals that have been enabled by a
previously issued OUTPut:TTLTRG<n>[:STATe] ON command.
If the module containing the channel is a scanner module, pulse the
appropriate front panel encode signal.
If another *TRG command is received before this sequence is complete, a SCPI
–211,“Trigger ignored” error message will be placed in the Error/Event queue.
The *TRG command will continue to have this effect until the trigger subsystem
is placed in the IDLE state. If additional *TRG commands are recieved after the
3–58
VX4380 256-Crosspoint Relay Matrix Module User Manual
IEEE-488.2 Common Commands
trigger system is placed in the IDLE state, the Option 01 will place a SCPI
–211,“Trigger Ignored” error message in the Error/Event queue.
The IEEE-488.2 Specification equates the *TRG command with an IEEE-488.1
Group Execute Trigger (GET) command. IEEE-488-to-VXI interface modules
typically convert IEEE-488.1 GET commands to VXI Trigger commands. For
this reason, the Option 01 equates the *TRG command with a VXI Trigger
command.
*TST?
Self Test query. In response to this query, the Option 01 performs a self test of
each of the switching modules under its control. During self test, the Option 01
verifies that it can properly control the relay drive circuitry of each switching
module under its control. After the self test is complete, each module is restored
to its pretest state. If all modules pass self test, an ASCII “0” is placed in the
Output buffer. If one or more modules fail the self test, an ASCII “1” is placed in
the Output buffer and error message(s) describing the failure are queued in the
Error/Event queue. Issue a SYSTem:ERRor? query to read these error messages.
*WAI
Wait to Continue. This command causes the module to wait until all pending
commands and queries are complete. All commands following *WAI are
suspended until the pending operations are complete.
VX4380 256-Crosspoint Relay Matrix Module User Manual
3–59
IEEE-488.2 Common Commands
3–60
VX4380 256-Crosspoint Relay Matrix Module User Manual
Status and Events
Status and Events
The Status and Event Reporting System reports asynchronous events and errors
that occur in the VX4380 256-Crosspoint Relay Matrix Module. This system
consists of four 8-bit registers and two queues that you access through the
command language. You can use these registers and queues to query the
instrument status and control the interrupts that report events.
In general, after an interrupt occurs, first conduct a serial poll, query the registers
to see why the interrupt occurred, and then send the SYSTem:ERRor? query to
see a descriptive error message.
This section describes the four registers and two queues of the Status and Event
Reporting system. For each register, you are given a description, a table
describing all of the bits, and an example of how to use the register.
The Status and Event Reporting process, synchronizing programming commands, and the system messages are also described in this section.
Status and Event Reporting System
The Status and Event Reporting system monitors and reports such events as an
error occurring or the availability of a response to a query. This system includes
descriptions of the following registers and queues:
Status Byte Register
H
Status Byte Register
H
Service Request Enable Register
H
Standard Event Status Register
H
Event Status Enable Register
H
Output queue
H
System Error and Event queue
The Status Byte Register, shown in Table 4–1, summarizes information from
other registers. Use a serial poll or a *STB? query to read the contents of the
Status Byte Register. The response is the sum of the decimal values for all bits
set. When you use a serial poll, bit 6 shows Request Service information. When
you use the *STB? query, bit 6, the Master Status Summary bit, indicates that
bits 5, 4, or 2 may be set.
VX4380 256-Crosspoint Relay Matrix Module User Manual
4–1
Status and Events
Table 4–1: The Status Byte Register
Bit
Decimal
Value
Function
0–1
–
Not used.
2
4
Error/Event queue Not Empty indicates that information is
contained in the Error/Event queue and is waiting to be read.
3
–
Not used.
4
16
Message Available shows that output is available in the Output
queue.
5
32
Event Status Bit indicates that one or more events have occurred
and the corresponding bits in the Standard Event Status Register
have been set.
6
64
Request Service (obtained from a serial poll) shows that the
VX4380 has requested service from the GPIB controller.
Master Status Summary (obtained from *STB? query) summarizes
the Event Status bit, Message Available bits, and Error/Event
queue Not Empty bits in the Status Byte Register.
7
–
Not used.
A common example of using the Status Byte register is to enable the Message
Available bit. This is done by sending an *SRE 16 command to the Option 01
VXI Interface Module. If the *STB? query returns a value of 80, bit 4 (decimal
value of 16) and bit 6 (decimal value of 64) have been set (giving a decimal sum
of 80). Bit 4 indicates that a message is available in the output queue. Bit 6
indicates that a bit in the Status Byte register that has been enabled by setting the
corresponding bit in the Service Request Enable register (in this case bit 4) has
been set.
Service Request Enable
Register
The Service Request Enable Register, shown in Table 4–2, controls which bits in
the Status Byte Register will generate a service request. Use the *SRE command
to set bits in the Service Request Enable Register. Use the *SRE? query to see
which bits in this register are enabled. The response from this query is the sum
of the decimal values for all bits set.
Table 4–2: The Service Request Enable Register
4–2
Bit
Decimal
Value
Function
0–1
–
Not used
2
4
Error/Event queue Bit indicates that a service request will be
generated when a message is placed in the Error/Event queue.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Status and Events
Table 4–2: The Service Request Enable Register (Cont.)
Bit
Decimal
Value
Function
3
8
Not used
4
16
Message Available Bit indicates that a service request will be
generated when a message is placed in the Output queue.
5
32
Event Status Bit indicates that events summarized in bit 5 of the
Status Byte Register will generate a service request.
6–7
–
Not used
If, for example, the *SRE? query returns a value of 48, bits 4 and 5 are set in the
Service Request Enable Register. Any event that causes the Message Available
bit (bit 4) or Event Status bit (bit 5) to be set in the Status Byte Register now
generates an interrupt. If you want an interrupt to be generated only when the
Event Status bit (bit 5) is set, use the *SRE 32 command.
Standard Event Status
Register
The Standard Event Status Register, shown in Table 4–3, records many types of
events that can occur in the VX4380. Use the *ESR? query to read the contents
of this register. The response is the sum of the decimal values for all bits set.
Reading this register clears all bits so the register can accumulate information
about new events.
Table 4–3: The Standard Event Status Register
Bit
Decimal
Value
0
1
Operation Complete shows that the operation is complete. This bit
is set when all pending operations complete following a *OPC
command.
1
–
Not used
2
4
Query Error shows that data in the Output queue was lost.
3
8
Not used
4
16
Execution Error shows that an error occurred while the VX4380
was executing a command or query. Table 4–6 on page 4–7 lists
the execution error messages.
5
32
Command Error shows that an error occurred while the VX4380
was parsing a command or query. Table 4–5 on page 4–7 lists the
command error messages.
6
–
Not used
7
128
Power On shows that the VX4380 was powered on.
Function
VX4380 256-Crosspoint Relay Matrix Module User Manual
4–3
Status and Events
The following example assumes that all bits have been enabled using the Event
Status Enable Register (see the next section for information about this register).
If a *ESR? query returns a value of 128, bit 7 (decimal value of 128) is set
indicating that the instrument is in the initial power-on state.
Event Status Enable
Register
The Event Status Enable Register, shown in Table 4–4, controls which events are
summarized in the Event Status bit (bit 5) of the Status Byte Register. Use the
*ESE command to set bits in the Event Status Enable Register. Use the *ESE?
query to see what bits in the Event Status Enable Register are set. The response
from this query is the sum of the decimal values for all bits summarized in the
event status bit of the Status Byte Register.
Table 4–4: The Event Status Enable Register
Bit
Decimal
Value
0
1
Set bit 5 of the Status Byte register when bit 1 (the Operation
Complete bit) of the Standard Event Status register is set.
1
2
Not used
2
4
Set bit 5 of the Status Byte register when bit 2 (the Query Error bit )
of the Standard Event Status register is set.
3
8
Not used
4
16
Set bit 5 of the Status Byte register when bit 4 (the Execution Error
bit) of the Standard Event Status register is set.
5
32
Set bit 5 of the Status Byte register when bit 5 (the Command Error
bit) of the Standard Event Status register is set.
6
64
Not used
7
128
Set bit 5 of the Status Byte register when bit 7 (the Power On bit) of
the Standard Event Status register is set.
Function
If, for example, the *ESE? query returns a value of 255, all bits are set,
indicating that all events will set the event status bit (bit 5) of the Status Byte
Register.
The Output Queue
The System Error and
Event Queue
4–4
The VX4380 stores query responses in the Output queue.
The VX4380 error and event messages are stored in the System Error and Event
queue. Use the SYSTem:ERRor? query to get the event number and a text
description of the event. Reading an event removes it from the queue. The Event
queue stores detailed information for up to 10 events; the events are stored in
first-in first-out order.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Status and Events
Status and Event Reporting Process
Figure 4–1 shows how to use the Status and Event Reporting system. In the
explanation that follows, numbers in parentheses refer to the circled numbers in
Figure 4–1.
1
7
Power
On
Standard Event Status
register
Read using *ESR?
6
—
5
4
3
Command Execution
Error
Error
2
Query
Error
1
—
2
Query
Error
1
—
—
0
Operation
Complete
—
0
Operation
Complete
Event
Event
Event
Event
queue
Byte
Byte
Byte
Output
queue
2
Event Status Enable
register
Read using *ESE?
Write using *ESE
7
Power
On
6
—
5
4
3
Command Execution
Error
Error
4
3
7
Status Byte
register
Read using *STB?
—
6
Request
Service 5
6
Master
Status
Event
Status Bit
6
Service Request Enable
register
Read using *SRE?
Write using *SRE
1
4
Message
Available
3
—
2
queue Not
Empty
1
—
0
—
5
7
6
—
5
—
Event
Status Bit
4
Message
Available
3
2
—
1
—
0
—
—
Figure 4–1: Status and Event Reporting Process
When an event occurs the appropriate bit in the Standard Event Status Register is
set to one and the event is recorded in the Event queue (1). If the corresponding
bit in the Event Status Enable Register is also enabled (2), then the event status
bit in the Status Byte Register is set to one (3).
VX4380 256-Crosspoint Relay Matrix Module User Manual
4–5
Status and Events
When output is sent to the Output queue (for example, a response to a query), the
message available bit in the Status Byte Register is set to one (4).
When a bit in the Status Byte Register is set to one and the corresponding bit in
the Service Request Enable Register is enabled (5), the master status summary
bit in the Status Byte Register is set to one and a service request is generated (6).
Messages
The VX4380 generates error messages in response to events caused by commands or queries. Each type of event sets a specific bit in the Standard Event
Status Register. Thus, each message is associated with a specific Standard Event
Status Register bit. In the message tables that follow, the associated Standard
Event Status Register bit is specified in the table title. Not shown in the tables
are secondary messages giving more detail about the cause of the error or the
meaning of the message. These secondary messages are shown for each
command and query in Syntax and Commands.
Table 4–5 shows the error messages generated by improper command syntax.
Check to see that the command is properly formatted and that it follows the rules
in Syntax and Commands.
Table 4–5: Command Error Messages (Bit 5 in Standard Event Status
Register)
Code
Message
–102
Syntax error; 2 dimensional <channel_spec> invalid for VX4350 module
–102
Syntax error; 3 dimensional <channel_spec> invalid for VX43xx module
–102
Syntax error; channel dimension mismatch
–102
Syntax error; integer field greater than 10 characters
–102
Syntax error; Missing module name
Syntax error; Module name already defined
4–6
–102
Syntax error; Module name already defined
–102
Syntax error; Module name length greater than 12 characters
–102
Syntax error; Non-contiguous section numbers
–102
Syntax error; ROUTe:CONFigure command invalid for VX43xx module
–102
Syntax error; ROUTe:DISJoin command invalid for VX43xx module
–102
Syntax error; ROUTe:JOIN command invalid for VX43xx module
–102
Syntax error; ROUTe:MODE command invalid for VX43xx module
–102
Syntax error; Undefined module name
–102
Syntax error; Unexpected x detected while ...
VX4380 256-Crosspoint Relay Matrix Module User Manual
Status and Events
Table 4–5: Command Error Messages (Bit 5 in Standard Event Status
Register) (Cont.)
Code
Message
–121
Invalid character in number
–123
Exponent too large
Table 4–6 lists the execution error messages that can occur during execution of a
command. Parameter y in these error messages represents the local bus address
of the module that the error message applies to. A value of 1 indicates the
module containing the Option 01 daughter board, a value of 2 the module in the
next slot to the right, and so on.
Table 4–6: Execution Error Messages (Bit 4 in Standard Event Status
Register)
Code
Message
–200
Execution error; Reserved
–200
Execution error; scan list undefined
–211
Trigger ignored
–213
Init ignored
–222
Data out of range; Channel number x on module y
–222
Data out of range; Channel number x!x on module y
–222
Data out of range; Channel number x!x!x on module y
–222
Data out of range; Invalid module address specified
–222
Data out of range; Invalid section number
–222
Data out of range; invalid sequence count
–222
Data out of range; invalid trigger delay
–222
Data out of range; Invalid VXI TTL Trigger level
–222
Data out of range; Maximum value for ESE command is 255
–222
Data out of range; Maximum value for SRE command is 255
–222
Data out of range; invalid dwell time specified.
–223
Too much data; channel list array overflow
–223
Too much data; Input buffer overflow
–223
Too much data; Output buffer full
–223
Too much data; scan list array overflow
–240
Hardware error; shift register verification error – module m
–241
Hardware error; Unrecognized module d, d
VX4380 256-Crosspoint Relay Matrix Module User Manual
4–7
Status and Events
Table 4–7 lists the device dependent error messages that can occur during
VX4380 operation.
Table 4–7: Device Dependent Error Messages (Bit 3 in Standard Event Status
Register)
4–8
Code
Message
–350
Queue overflow; error/event queue
–350
Queue overflow; output queue
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendices
Appendix A: Specifications
Table A–1: VXI Instrument Characteristics
Characteristics
Description
VXI General Characteristics
The instrument provides a VXI interface that complies with Revision 1.4.
The VXI interface is defined by the VXI Consortium, Inc.
Interface Type
Message Based (1.4)
Protocols
Word Serial (WSP)
TTL Outputs
VXI TTLTRG* Lines TTLTRG0* through TTLTRG7* under program control.
Product Compliance to Regulations
(VX4320, VX4330, VX4350, VX4380 only)
Product Safety
UL listed UL 3111–1
UL listed CAN/CSA C22.2 NO.1010–1
UL classified to IEC–1010–1.
IEC Characteristics
Overvoltage Category:
Safety:
EMC
Per EC Council Directive 89/336 EEC (EC–92), the following standards and limits
apply to the requirements for equipment to be used in residential, commercial, and
light industrial environments. They are specified in EN–50081–1, the Generic
Emission Standard, and in EN 50082–1, the Generic Immunity Standard. For
equipment that is also intended to be used in industrial environments, the standards
and limits specified in EN 50081–2 and EN 50082–2 should be used in addition.
Emissions
CAT l
Class l
Emissions shall be within the limits specified by the following requirements:
Enclosure:
EN 55011 Class A limit for radiated emissions.
AC Mains:
EN 55011 Class A limit for radiated emissions.
EN 60555–2: Power line harmonics
Immunity, Enclosure, Radio Frequen- No state change when the instrument is subjected to a 3 V/M electromagnetic field
cy Electromagnetic Field; IEC 801–3 over the frequency range of 27 MHz to 500 MHz.
Immunity, Enclosure, Electrostatic
Discharge (ESD); IEC 801–2
Up to 8 kV with no loss of stored data, change to control settings, degradation of
performance, or temporary loss of function. No state change.
Immunity, Fast Transients, Common
Mode; IEC 801–4
No loss of stored data, change to control settings, degradation of performance, or
temporary loss of function will occur when the instrument is subjected to the transients
as described below.
Port
Peak Voltage – kV
Tr/Th – ns
Rep. Freq. – kHz
Signal & control
0.5
5/50
5
AC Power
1
5/50
5
VX4380 256-Crosspoint Relay Matrix Module User Manual
A–1
Appendix A: Specifications
Table A–1: VXI Instrument Characteristics
Characteristics
EN 55011, Class A
FCC
Description
The instrument complies with the requirements of EN 55011 for radiated, conducted,
and magnetic emissions, when installed in a suitable VXI chassis. A suitable VXI
chassis is defined as one which contains adequate EMC shielding which makes
contact with the RF gasket on the front and rear shields of the VX43xx Module.
The instrument complies with the requirements of FCC CFR 47, Part 15, Subpart B,
Class A for radiated and conducted emissions.
Table A–2: Environmental/Reliability Characteristics
Characteristics
Description
Temperature
Operating
Meets or exceeds MIL-T-28800E for Type III, 0 to 50_ C external ambient, when
operated in a mainframe providing Class 3 equipment.
Non-operating
–40_ C to +71_ C
Airflow of at least 1.57 liters/sec at 0.05 mm H2O air pressure, –10_ C/55_ C for 10_
C (or less) temperature rise of internal air, as measured at the cooling air exit points,
and with no heat transfer either to or from any adjacent VXI modules.
Humidity
Operating
Up to 95% at up to 30_ C, and up to 45%, at up to 50_ C.
Non-operating
Up to 95%, at up to 50_ C.
Altitude (1) Operating
6,000 ft. altitude.
Altitude (2)
Meets or exceeds MIL-T-28800E for Type III, (operating to 10,000 ft., non-operating
to 15,000 ft.). Derate maximum operating temperature above TBD ft. by degree C per
1000 ft.
Table A–3: VX4380-Specific Characteristics
Characteristics
Description
VME Interrupter Level
Switch selectable to a level between 1 and 7.
VXI Logical Address
Switch selectable to a value between 0 and 254.
VXI Dynamic Addressing
Not supported.
Contents of device/manufacturer dependent
VXI registers.
A–2
ID Register
BFFD hexadecimal.
Device Type
Set according to the model number of the slave module that the interface is installed
on as specified in the following table. (Convert the last 3 digits of the model number to
hex, take the one’s complement, AND with F7FF.)
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix A: Specifications
Table A–3: VX4380-Specific Characteristics (Cont.)
Characteristics
Description
Slave Module Model No.
Register Contents (hexadecimal)
VX4320
F6BF
VX4330
F6B5
VX4350
F6A1
VX4380
F683
VXI TTL Trigger Outputs
One or more of the VXI TTLTRG* signals may be driven. All TTLTRG* outputs may be
disabled.
VXI TTL Trigger Inputs
One of the VXI TTLTRG* signals may be selected to be polled or to act as an interrupt
source to the module’s microprocessor.
Configuration
4 4 × 16 2-wire matrices
Current
Voltage
+5 V Supply
Maximum Average Current
3.90 A
Fused
10 A
Table A–4: Relay Switching Characteristics
Characteristics
Description
Maximum Switching Voltages
Terminals
DC
AC/RMS
V Peak
HI to LO
220
250
354
HI to Chassis
250
250
354
LO to Chassis
250
250
354
Terminals
<30 VDC
<30 VAC/RMS
per channel
2A
2A
per common
2A
2A
Terminals
<220 VDC
<250 VAC/RMS
per channel
60 W
125 VA
per common
60 W
125 VA
Loading
Operations
No Load
1 × 108
30 VDC 2 A
1 × 105
30 VDC 1 A
2 × 105
125 VAC 1 A
1 × 105
Maximum Switching Current (non-inductive)
Maximum Switching Power (non-inductive)
Rated Switching Operations
VX4380 256-Crosspoint Relay Matrix Module User Manual
A–3
Appendix A: Specifications
Table A–5: Switching Channel Characteristics
Characteristics
Description
Bandwidth (–3 dB) Characteristics – 50 W
Bala e Source/Load
Balanced
o e Loa
Circuit
Bandwidth
1 crosspoint closed in a 4 × 16 matrix
>15 MHz (>30 MHz typical)
1 crosspoint closed in a 16 × 16 matrix
>15 MHz (>30 MHz typical)
Frequency/Isolation
Crosstalk/Isolation
10 K
< –80 dB
100 kHz
< –60 dB
1 MHz
< –40 dB
Channel to Channel Crosstalk/Open Channel
Isolatio
Isolation
Table A–6: Signal Path
Characteristics
Description
Signal Path Thermal Offset
Offset Voltage: <7 mV
Insulation Resistance
Condition
Contact Resistance
Initial
< 1.5 W
After Rated Operations
< 3.5 W
> 5 × 108 W @ +25_ C, 40% RH
> 5 × 106 W @ +40_ C, 95% RH
Table A–7: Cabling
Characteristics
Description
Recommended Cable
VX1660 Analog Cable, 5 meters
Cable kit
VX1630S 160-pin Connector Kit
Table A–7: Power Distribution
Characteristics
Description
+5 VDC Current
3.90 A
A–4
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix B: Input/Output Connections
The front panel connector pinouts for the VX4380 are shown in the tables on the
following pages.
VX4380 256-Crosspoint Relay Matrix Module User Manual
B–1
Appendix B: Input/Output Connections
32
Section 4
17
16
Section 3
1
32
Section 2
17
16
Section 1
a bcd e
1
Figure B–1: VX4380 Front Panel
B–2
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix B: Input/Output Connections
Table B–1: VX4380 Upper Connector (J401) Pinout
Pin No.
Sect.
32
Col16Lo
Col16Hi
Row1Lo
Col16Hi
Col16Lo
4
31
Col15Lo
Col15Hi
Row1Hi
Col15Hi
Col15Lo
4
30
Col14Lo
Col14Hi
Row2Lo
Col14Hi
Col14Lo
4
29
Col13Lo
Col13Hi
Row2Hi
Col13Hi
Col13Lo
4
28
Col12Lo
Col12Hi
Row3Lo
Col12Hi
Col12Lo
4
27
Col11Lo
Col11Hi
Row3Hi
Col11Hi
Col11Lo
4
26
Col10Lo
Col10Hi
Row4Lo
Col10Hi
Col10Lo
4
25
Col09Lo
Col09Hi
Row4Hi
Col09Hi
Col09Lo
4
24
Col08Lo
Col08Hi
Row4Hi
Col08Hi
Col08Lo
4
23
Col07Lo
Col07Hi
Row4Lo
Col07Hi
Col07Lo
4
22
Col06Lo
Col06Hi
Row3Hi
Col06Hi
Col06Lo
4
21
Col05Lo
Col05Hi
Row3Lo
Col05Hi
Col05Lo
4
20
Col04Lo
Col04Hi
Row2Hi
Col04Hi
Col04Lo
4
19
Col03Lo
Col03Hi
Row2Lo
Col03Hi
Col03Lo
4
18
Col02Lo
Col02Hi
Row1Hi
Col02Hi
Col02Lo
4
17
Col01Lo
Col01Hi
Row1Lo
Col01Hi
Col01Lo
4
16
Col16Lo
Col16Hi
Row1Lo
Col16Hi
Col16Lo
3
15
Col15Lo
Col15Hi
Row1Hi
Col15Hi
Col15Lo
3
14
Col14Lo
Col14Hi
Row2Lo
Col14Hi
Col14Lo
3
13
Col13Lo
Col13Hi
Row2Hi
Col13Hi
Col13Lo
3
12
Col12Lo
Col12Hi
Row3Lo
Col12Hi
Col12Lo
3
11
Col11Lo
Col11Hi
Row3Hi
Col11Hi
Col11Lo
3
10
Col10Lo
Col10Hi
Row4Lo
Col10Hi
Col10Lo
3
9
Col09Lo
Col09Hi
Row4Hi
Col09Hi
Col09Lo
3
8
Col08Lo
Col08Hi
Row4Hi
Col08Hi
Col08Lo
3
7
Col07Lo
Col07Hi
Row4Lo
Col07Hi
Col07Lo
3
6
Col06Lo
Col06Hi
Row3Hi
Col06Hi
Col06Lo
3
5
Col05Lo
Col05Hi
Row3Lo
Col05Hi
Col05Lo
3
4
Col04Lo
Col04Hi
Row2Hi
Col04Hi
Col04Lo
3
3
Col03Lo
Col03Hi
Row2Lo
Col03Hi
Col03Lo
3
2
Col02Lo
Col02Hi
Row1Hi
Col02Hi
Col02Lo
3
1
Col01Lo
Col01Hi
Row1Lo
Col01Hi
Col01Lo
3
Pin
a
b
c
d
e
VX4380 256-Crosspoint Relay Matrix Module User Manual
B–3
Appendix B: Input/Output Connections
Table B–2: VX4380 Lower Connector (J1201) Pinout
Pin No.
Sect.
32
Col16Lo
Col16Hi
Row1Lo
Col16Hi
Col16Lo
2
31
Col15Lo
Col15Hi
Row1Hi
Col15Hi
Col15Lo
2
30
Col14Lo
Col14Hi
Row2Lo
Col14Hi
Col14Lo
2
29
Col13Lo
Col13Hi
Row2Hi
Col13Hi
Col13Lo
2
28
Col12Lo
Col12Hi
Row3Lo
Col12Hi
Col12Lo
2
27
Col11Lo
Col11Hi
Row3Hi
Col11Hi
Col11Lo
2
26
Col10Lo
Col10Hi
Row4Lo
Col10Hi
Col10Lo
2
25
Col09Lo
Col09Hi
Row4Hi
Col09Hi
Col09Lo
2
24
Col08Lo
Col08Hi
Row4Hi
Col08Hi
Col08Lo
2
23
Col07Lo
Col07Hi
Row4Lo
Col07Hi
Col07Lo
2
22
Col06Lo
Col06Hi
Row3Hi
Col06Hi
Col06Lo
2
21
Col05Lo
Col05Hi
Row3Lo
Col05Hi
Col05Lo
2
20
Col04Lo
Col04Hi
Row2Hi
Col04Hi
Col04Lo
2
19
Col03Lo
Col03Hi
Row2Lo
Col03Hi
Col03Lo
2
18
Col02Lo
Col02Hi
Row1Hi
Col02Hi
Col02Lo
2
17
Col01Lo
Col01Hi
Row1Lo
Col01Hi
Col01Lo
2
16
Col16Lo
Col16Hi
Row1Lo
Col16Hi
Col16Lo
1
15
Col15Lo
Col15Hi
Row1Hi
Col15Hi
Col15Lo
1
14
Col14Lo
Col14Hi
Row2Lo
Col14Hi
Col14Lo
1
13
Col13Lo
Col13Hi
Row2Hi
Col13Hi
Col13Lo
1
12
Col12Lo
Col12Hi
Row3Lo
Col12Hi
Col12Lo
1
11
Col11Lo
Col11Hi
Row3Hi
Col11Hi
Col11Lo
1
10
Col10Lo
Col10Hi
Row4Lo
Col10Hi
Col10Lo
1
9
Col09Lo
Col09Hi
Row4Hi
Col09Hi
Col09Lo
1
8
Col08Lo
Col08Hi
Row4Hi
Col08Hi
Col08Lo
1
7
Col07Lo
Col07Hi
Row4Lo
Col07Hi
Col07Lo
1
6
Col06Lo
Col06Hi
Row3Hi
Col06Hi
Col06Lo
1
5
Col05Lo
Col05Hi
Row3Lo
Col05Hi
Col05Lo
1
4
Col04Lo
Col04Hi
Row2Hi
Col04Hi
Col04Lo
1
3
Col03Lo
Col03Hi
Row2Lo
Col03Hi
Col03Lo
1
2
Col02Lo
Col02Hi
Row1Hi
Col02Hi
Col02Lo
1
1
Col01Lo
Col01Hi
Row1Lo
Col01Hi
Col01Lo
1
Pin
a
b
c
d
e
B–4
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix B: Input/Output Connections
Figure B–2: Matrix Configuration
VX4380 256-Crosspoint Relay Matrix Module User Manual
B–5
Appendix B: Input/Output Connections
B–6
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix C: Examples
In these examples an Option 01 daughter board is installed on a VX4380
Module. Two additional VX4380 Modules are installed in consecutive slots to
the right of the first VX4380.
Example 1
H
Reset the modules. This command places the VX4380 Modules in their
power-on state. All channels on all VX4380 Modules are opened. This
command also clears the Output queue, Error/Event queue, and the Standard
Event Status register.
WRITE
H
Reset the modules. Open all channels on all VX4380 Modules but do not
clear the Output queue, the Error/Event queue, or the Standard Event Status
register.
WRITE
H
H
WRITE
route:module:catalog?
READ
"M1", "M2", "M3"
Close the relay that joins row 4 to column 15 in section 2 on the third
VX4380.
close (@m3(4!15!2))
Change the module name assignments of the relay modules to ”MATRIX_1”, ”MATRIX_2”, and ”MATRIX_3”.
WRITE
matrix_3,3
H
*CLS
Query the default module names assigned to the modules.
WRITE
H
*RST
Clear the Output queue, the Error/Event queue, and the Standard Event
Status register, but do not change the state of the VX4380 Modules.
WRITE
H
system:preset
mod:def matrix_1,1; def matrix_2,2; def
Query the new module names.
WRITE
route:module:catalog?
READ
"MATRIX_1", "MATRIX_2", "MATRIX_3"
VX4380 256-Crosspoint Relay Matrix Module User Manual
C–1
Appendix C: Examples
H
Enable VXI TTL trigger 3.
WRITE
H
output:ttltrg3:State on
Assign a close dwell time of 0.25 seconds to each of the VX4380 Modules.
WRITE
m3,0.25
close:dwell m1,0.25; dwell m2,0.25; dwell
Note that this command is equivalent to the following three commands.
H
WRITE
close:dwell m1,0.25
WRITE
close:dwell m2,0.25
WRITE
close:dwell m3,0.25
Open all relays on the first and second VX4380 Modules.
WRITE
H
Close the relays that join row 1 to columns 10 through 16 in section 3 of the
first VX4380, the relays that join row 3 to columns 1 and 2 in section 2 of
the second VX4380, and the relays that join rows 1 through 4 to column 6 in
section 2 of the third VX4380. After closing these relays, wait 0.25 seconds
then pulse VXI TTL trigger 3 low for 3 sec.
WRITE
H
H
open:all matrix_1; all matrix_2
close (@matrix_1(1!10!3:1!16!3),
matrix_2(3!1!2,3!2!2), matrix_3(1!6!2:4!6!2))
Query the close state of the relays in section 2 of the first VX4380.
WRITE
close? (@matrix_1(1!1!2:4!16!2))
READ
0 0 0
0 0 0
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0 0 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
0 0 0 0 0 0 0 0 0 0
The close states are returned in the same order in which they are specified in
the close query. In this example the specified order is:
1!1!2,1!2!2,1!3!2, ..., 1!16!2
2!1!2,2!2!2,2!3!2, ..., 2!16!2
3!1!2,3!2!2,3!3!2, ..., 3!16!2
4!1!2,4!2!2,4!3!2, ..., 4!16!2
Note that this query is equivalent to the following close query:
close? (@matrix_1(65:128))
C–2
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix C: Examples
H
Define a scan sequence consisting of the relays that join row 1 to columns 1
through 16 in section 3 of the second VX4330. Note that this command
causes all relays in the scan list to be opened.
WRITE
H
scan (@matrix_2(1!1!3:1!16!3))
Set the trigger source for the defined scan list to “immediate”. This causes
the Option 01 daughter board to generate its own internal triggers. Each time
a trigger is generated, the following sequence of events occurs:
Wait for the trigger delay defined by the TRIGger[:SEQuence]:DELay
command to expire.
Open the relay in the scan list that is currently closed.
Wait for the open dwell time assigned to the module containing the relay
just opened to expire.
Close the next relay in the scan list.
Wait for the close dwell time assigned to the module containing the relay
just closed to expire.
Pulse any enabled VXI TTL triggers low for 3 sec.
In this case, the default trigger delay of 0 is used, the default open dwell time
of 0 is used, and the close dwell time has been set to 0.25 seconds. Note that
the second and third events are skipped when the first trigger is received.
The last three events are skipped when the last trigger is received. Triggers
are not recognized until an INITiate[:IMMediate] or an INITiate:Continuous
command is received.
H
Set the number of times to scan through the defined scan list to 2, to begin
when an INITiate[:IMMediat] command is received.
WRITE
H
Scan through the entire scan list two times.
WRITE
H
initiate
Set the Operation Complete bit in the Standard Event Status register after the
scan list has been sequenced two times.
WRITE
H
trigger:sequence:count 2
*opc
Poll the Operation Complete bit in the Standard Event Status register to see
when the scan sequence is finished.
WRITE
*esr?
READ
<nr1>
VX4380 256-Crosspoint Relay Matrix Module User Manual
C–3
Appendix C: Examples
The <nr1> response is a 3-digit ASCII-encoded integer. If the value of this
number is odd, the Operation Complete bit is set.
H
Scan through the entire scan list repeatedly until an ABORt command is
received.
WRITE
H
initiate:continuous
Stop sequencing through the scan list. Open the relay that was closed last.
WRITE
abort
Example 2
H
Make sure that all of the crosspoint relays are open.
WRITE
H
Close the 2-wire connection between row 1 and column 1 of section 1.
WRITE
H
C–4
ROUTE:CLOSE (@M1(2!7!3))
Open the 2-wire connection between row 1 and column 1 of section 1.
WRITE
H
ROUTE:CLOSE (@M1(1!1!1))
Close the 2-wire connection between row 2 and column 7 of section 3.
WRITE
H
ROUTE:OPEN:ALL M1
ROUTE:OPEN (@M1(1!1!1))
Check for system errors.
WRITE
SYSTEM:ERR?
READ
0, "No error"
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix D: User Service
This appendix contains service-related information for the VX4380 that covers
the following topics:
H
Performance verification
H
Preventive maintenance
H
Troubleshooting
H
User-replaceable parts
Performance Verification
You may use the Operational Check procedure listed in Getting Started to verify
that the module is operating correctly. The instrument has been fully tested and
calibrated before leaving the factory.
If the self test or diagnostic commands indicate a failure, contact your Tektronix
field office or representative for assistance.
Preventive Maintenance
You should perform inspection and cleaning as preventive maintenance.
Preventive maintenance, when done regularly, may prevent VX4380 malfunction
and enhance reliability. Inspect and clean the VX4380 as often as conditions
require by following these steps:
1. Turn off power and remove the VX4380 from the VXIbus mainframe.
2. Remove loose dust on the outside of the instrument with a lint-free cloth.
3. Remove any remaining dirt with a lint-free cloth dampened with water or a
75% isopropyl alcohol solution. Do not use abrasive cleaners.
Troubleshooting
If you suspect a malfunction, first double check connections to and from the
VX4380. If the trouble persists, perform the Functional Check.
If the self test indicates a failure, contact your Tektronix field office or representative for assistance.
VX4380 256-Crosspoint Relay Matrix Module User Manual
D–1
Appendix D: User Service
User-Replaceable Parts
Refer to Appendix E for replaceable parts information.
D–2
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix E: Replaceable Parts
This section contains a list of the replaceable modules for the <instrument>. Use
this list to identify and order replacement parts.
Parts Ordering Information
Replacement parts are available through your local Tektronix field office or
representative.
Changes to Tektronix products are sometimes made to accommodate improved
components as they become available and to give you the benefit of the latest
improvements. Therefore, when ordering parts, it is important to include the
following information in your order.
H
Part number
H
Instrument type or model number
H
Instrument serial number
H
Instrument modification number, if applicable
If you order a part that has been replaced with a different or improved part, your
local Tektronix field office or representative will contact you concerning any
change in part number.
Change information, if any, is located at the rear of this manual.
Module Servicing
Modules can be serviced by selecting one of the following three options. Contact
your local Tektronix service center or representative for repair assistance.
Module Exchange. In some cases you may exchange your module for a remanufactured module. These modules cost significantly less than new modules and
meet the same factory specifications. For more information about the module
exchange program, call 1-800-TEK-WIDE, extension 6630.
Module Repair and Return. You may ship your module to us for repair, after which
we will return it to you.
New Modules. You may purchase replacement modules in the same way as other
replacement parts.
VX4380 256-Crosspoint Relay Matrix Module User Manual
E–1
Appendix E: Replaceable Parts
Using the Replaceable Parts List
This section contains a list of the mechanical and/or electrical components that
are replaceable for the <instrument>. Use this list to identify and order replacement parts. The following table describes each column in the parts list.
Parts List Column Descriptions
Column
Column Name
Description
1
Figure & Index Number
Items in this section are referenced by figure and index numbers to the exploded view
illustrations that follow.
2
Tektronix Part Number
Use this part number when ordering replacement parts from Tektronix.
3 and 4
Serial Number
Column three indicates the serial number at which the part was first effective. Column four
indicates the serial number at which the part was discontinued. No entries indicates the part is
good for all serial numbers.
5
Qty
This indicates the quantity of parts used.
6
Name & Description
An item name is separated from the description by a colon (:). Because of space limitations, an
item name may sometimes appear as incomplete. Use the U.S. Federal Catalog handbook
H6-1 for further item name identification.
7
Mfr. Code
This indicates the code of the actual manufacturer of the part.
8
Mfr. Part Number
This indicates the actual manufacturer’s or vendor’s part number.
Abbreviations
Mfr. Code to Manufacturer
Cross Index
E–2
Abbreviations conform to American National Standard ANSI Y1.1–1972.
The table titled Manufacturers Cross Index shows codes, names, and addresses
of manufacturers or vendors of components listed in the parts list.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix E: Replaceable Parts
Manufacturers Cross Index
Mfr.
Code
Manufacturer
Address
City, State, Zip Code
0KB01
STAUFFER SUPPLY CO
810 SE SHERMAN
PORTLAND, OR 97214–4657
0KB05
NORTH STAR NAMEPLATE INC
5750 NE MOORE COURT
HILLSBORO, OR 97124–6474
22526
BERG ELECTRONICS INC
857 OLD TRAIL ROAD
ETTERS, PA 17319
30817
INSTRUMENT SPECIALTIES CO INC
EXIT 53, RT 80
BOX A
DELAWARE WATER GAP, PA 18327
61857
SAN–O INDUSTRIAL CORP
91–3 COLIN DRIVE
HOLBROOK, NY 11741
80009
TEKTRONIX INC
14150 SW KARL BRAUN DR
PO BOX 500
BEAVERTON, OR 97077–0001
93907
CAMCAR DIV OF TEXTRON INC
ATTN: ALICIA SANFORD
516 18TH AVE
ROCKFORD, IL 611045181
TK1943
NEILSEN MANUFACTURING INC
3501 PORTLAND RD NE
SALEM, OR 97303
TK2548
XEROX CORPORATION
DIV OF XEROX CORPORATION
14181 SW MILLIKAN WAY
BEAVERTON, OR 97005
TK2647
INSTRUMENT SPECIALITIES INC
C/O TEMCO NW
1336 SE 51ST STREET
HILLSBORO, OR 97123
VX4380 256-Crosspoint Relay Matrix Module User Manual
E–3
Appendix E: Replaceable Parts
Replaceable Parts List
Fig. &
Index
Number
Tektronix
Part Number
Serial No.
Effective
Serial No.
Discont’d
Qty
Name & Description
Mfr. Code
Mfr. Part Number
070–9182–XX
1
MANUAL,TECH:USERS
80009
070–9182–XX
070–9202–XX
1
MANUAL,TECH:REFERENCE GUIDE
TK2548
070–9202–XX
1
334–8951–00
1
MARKER,IDENT:MARKED VX4380
0KB05
2
367–0411–00
1
HANDLE,EJECTOR:TOP,SINGLE WIDE
3
950–4827–00
2
SCREW PHIL M 2.5 X 8 CSK
0KB01
950–4827–00
4
950–4448–00
2
SCREW M2.5X10 CHEESEHEAD
80009
950–4448–00
5
950–3794–00
2
WAVY 2.7MM
80009
950–3794–00
6
159–0193–00
1
FUSE,WIRE LEAD:10A,60V,FAST BLOW,5 SEC,
61857
SP5–10A
7
163–0384–00
1
IC,DIGITAL:CMOS,PRGM
80009
163–0384–00
8
386–6862–00
1
PANEL,VXI:END CAP,VXI APPLICATION
TK1943
386–6862–00
9
348–1434–00
4
GASKET,EMI:2.912 L,CLIP ON,BE CU EMI
GASKET,TIN PLATED
30817
97–613–17–029
10
211–0373–00
7
SCREW,MACHINE:4–40 X
0.250,PNH,STL,CDPL,T–10
93907
ORDER BY
DESCRIPTION
11
200–4231–00
1
COVER:VXI APPLICATION
TK1943
200–4231–00
12
334–8971–00
1
MARKER,IDENT:MATRIX CONFIGURATION
LABEL,VX4380
0KB05
334–8971–00
13
131–3199–00
128
CONN,SHUNT:SHUNT,FEMALE,STR,1 X 2,0.1 CTR
22526
68786–202
14
367–0410–00
1
HANDLE,EJECTOR:BOTTOM,SINGLE WIDE
MODULE
15
211–0391–00
5
SCR,ASSEM,WSHR:2–56 X 0.437,
PNH,STL,CDPL,T–8
93907
ORDER BY
DESCRIPTION
16
334–8952–00
1
MARKER,IDENT:MARKED VXIBUS & RELAY MATRIX
0KB05
334–8952–00
17
351–0984–00
2
GUIDE:BOTTOM GUIDE,5 ROW
TK1943
351–0984–00
18
351–0983–00
2
GUIDE:TOP GUIDE,5 ROW
TK1943
351–0983–00
19
348–1365–01
1
SHLD GSKT,ELEC:SYMETRICAL SLOTTED FINGER
MTG,SNAP–IN
TK2647
348–1365–01
20
214–4692–01
1
KEY:VXI,TTL
80009
214–4692–01
E–4
334–8951–00
20817–328
20817–327
VX4380 256-Crosspoint Relay Matrix Module User Manual
Appendix E: Replaceable Parts
8
3
5
4
2
9
10
9
2
1
11
6
7
20
10
15
18
12
13
15
17
19
4
5
18
14
17
3
16
14
15
Figure E–1: VX4380 Exploded View
VX4380 256-Crosspoint Relay Matrix Module User Manual
E–5
Appendix E: Replaceable Parts
E–6
VX4380 256-Crosspoint Relay Matrix Module User Manual
Glossary and Index
Glossary
The terms in this glossary are defined as used in the VXIbus System. Although
some of these terms may have different meanings in other systems, it is
important to use these definitions in VXIbus applications. Terms which apply
only to a particular instrument module are noted. Not all terms appear in every
manual.
Accessed Indicator
An amber LED indicator that lights when the module identity is selected by
the Resource Manager module, and flashes during any I/O operation for the
module.
ACFAIL*
A VMEbus backplane line that is asserted under these conditions: 1) by the
mainframe Power Supply when a power failure has occurred (either AC line
source or power supply malfunction), or 2) by the front panel ON/
STANDBY switch when switched to STANDBY.
Asynchronous Communication
Communications that occur outside the normal “command-response” cycle.
Such communications have higher priority than synchronous communication.
Backplane
The printed circuit board that is mounted in a VXIbus mainframe to provide
the interface between VXIbus modules and between those modules and the
external system.
Bus Arbitration
In the VMEbus interface, a system for resolving contention for service
among VMEbus Master devices on the VMEbus.
Bus Timer
A functional module that measures the duration of each data transfer on the
Data Transfer Bus (DTB) and terminates the DTB cycle if the duration is
excessive. Without the termination capability of this module, a Bus Master
attempt to transfer data to or from a non-existent Slave location could result
in an infinitely long wait for the Slave response.
Client
In shared memory protocol (SMP), that half of an SMP channel that does not
control the shared memory buffers.
CLK10
A 10 MHz, ±100 ppm, individually buffered (to each module slot),
differential ECL system clock that is sourced from Slot 0 and distributed to
VX4380 256-Crosspoint Relay Matrix Module User Manual
Glossary–1
Glossary
Slots 1–12 on P2. It is distributed to each module slot as a single source,
single destination signal with a matched delay of under 8 ns.
Commander
In the VXIbus interface, a device that controls another device (a servant). A
commander may be a servant of another commander.
Command
A directive to a device. There are three types of commands:
In Word Serial Protocol, a 16-bit imperative to a servant from its commander.
In Shared Memory Protocol, a 16-bit imperative from a client to a server, or
vice versa.
In a Message, an ASCII-coded, multi-byte directive to any receiving device.
Communication Registers
In word serial protocol, a set of device registers that are accessible to the
commander of the device. Such registers are used for inter-device communications, and are required on all VXIbus message-based devices.
Configuration Registers
A set of registers that allow the system to identify a (module) device type,
model, manufacturer, address space, and memory requirements. In order to
support automatic system and memory configuration, the VXIbus standard
specifies that all VXIbus devices have a set of such registers, all accessible
from P1 on the VMEbus.
C-Size Card
A VXIbus instrument module that is 340.0 mm × 233.4 mm × 30.48 mm
(13.4 in. × 9.2 in × 1.2 in).
Custom Device
A special-purpose VXIbus device that has configuration registers so as to be
identified by the system and to allow for definition of future device types to
support further levels of compatibility.
Data Transfer Bus
One of four buses on the VMEbus backplane. The Data Transfer Bus allows
Bus Masters to direct the transfer of binary data between Masters and Slaves.
DC SUPPLIES Indicator
A red LED indicator that illuminates when a DC power fault is detected on
the backplane.
Device Specific Protocol
A protocol for communication with a device that is not defined in the
VXIbus specification.
Glossary–2
VX4380 256-Crosspoint Relay Matrix Module User Manual
Glossary
D-Size Card
A VXIbus instrument module that is 340.0 × 366.7 mm × 30.48 mm (13.4 ×
14.4 in × 1.2 in).
DTB
See Data Transfer Bus.
DTB Arbiter
A functional module that accepts bus requests from Requester modules and
grants control of the DTB to one Requester at a time.
DUT
Device Under Test.
ECLTRG
Six single-ended ECL trigger lines (two on P2 and four on P3) that function
as inter-module timing resources, and that are bussed across the VXIbus
subsystem backplane. Any module, including the Slot 0 module, may drive
and receive information from these lines. These lines have an impedance of
50 W; the asserted state is logical High.
Embedded Address
An address in a communications protocol in which the destination of the
message is included in the message.
ESTST
Extended STart/STop protocol; used to synchronize VXIbus modules.
Extended Self Test
Any self test or diagnostic power-on routine that executes after the initial
kernel self test program.
External System Controller
The host computer or other external controller that exerts overall control
over VXIbus operations.
FAILED Indicator
A red LED indicator that lights when a device on the VXIbus has detected an
internal fault. This might result in the assertion of the SYSFAIL* line.
IACK Daisy Chain Driver
The circuit that drives the VMEbus Interrupt Acknowledge daisy chain line
that runs continuously through all installed modules or through jumpers
across the backplane.
ID-ROM
An NVRAM storage area that provides for non-volatile storage of diagnostic
data.
Instrument Module
A plug-in printed circuit board, with associated components and shields, that
VX4380 256-Crosspoint Relay Matrix Module User Manual
Glossary–3
Glossary
may be installed in a VXIbus mainframe. An instrument module may
contain more than one device. Also, one device may require more than one
instrument module.
Interface Device
A VXIbus device that provides one or more interfaces to external equipment.
Interrupt Handler
A functional module that detects interrupt requests generated by Interrupters
and responds to those requests by requesting status and identity information.
Interrupter
A device capable of asserting VMEbus interrupts and performing the
interrupt acknowledge sequence.
IRQ
The Interrupt ReQuest signal, which is the VMEbus interrupt line that is
asserted by an Interrupter to signify to the controller that a device on the bus
requires service by the controller.
Local Bus
A daisy-chained bus that connects adjacent VXIbus slots.
Local Controller
The instrument module that performs system control and external interface
functions for the instrument modules in a VXIbus mainframe or several
mainframes. See Resource Manager.
Local Processor
The processor on an instrument module.
Logical Address
The smallest functional unit recognized by a VXIbus system. It is often used
to identify a particular module.
Mainframe
Card Cage. For example, the Tektronix VX1410 Intelliframe, an operable
housing that includes 13 C-size VXIbus instrument module slots.
Memory Device
A storage element (such as bubble memory, RAM, and ROM) that has
configuration registers and memory attributes (such as type and access time).
Message
A series of data bytes that are treated as a single communication, with a well
defined terminator and message body.
Message Based Device
A VXIbus device that supports VXI configuration and communication
registers. Such devices support the word serial protocol, and possibly other
message-based protocols.
Glossary–4
VX4380 256-Crosspoint Relay Matrix Module User Manual
Glossary
MODID Lines
Module/system identity lines.
Physical Address
The address assigned to a backplane slot during an access.
Power Monitor
A device that monitors backplane power and reports fault conditions.
P1
The top-most backplane connector for a given module slot in a vertical
mainframe. The left-most backplane connector for a given slot in a horizontal mainframe.
P2
The bottom backplane connector for a given module slot in a vertical C-size
mainframe; or the middle backplane connector for a given module slot in a
vertical D-size mainframe such as the VX1500.
Query
A form of command that allows for inquiry to obtain status or data.
READY Indicator
A green LED indicator that lights when the power-on diagnostic routines
have been completed successfully. An internal failure or failure of +5 V
power will extinguish this indicator.
Register Based Device
A VXIbus device that supports VXI register maps, but not high level
VXIbus communication protocols; includes devices that are register-based
servant elements.
Requester
A functional module that resides on the same module as a Master or
Interrupt Handler and requests use of the DTB whenever its Master or
Interrupt Handler requires it.
Resource Manager
A VXIbus device that provides configuration management services such as
address map configuration, determining system hierarchy, allocating shared
system resources, performing system self test diagnostics, and initializing
system commanders.
Self Calibration
A routine that verifies the basic calibration of the instrument module circuits,
and adjusts this calibration to compensate for short- and long-term variables.
Self Test
A set of routines that determine if the instrument module circuits will
VX4380 256-Crosspoint Relay Matrix Module User Manual
Glossary–5
Glossary
perform according to a given set of standards. A self test routine is performed upon power-on.
Servant
A VXIbus message-based device that is controlled by a commander.
Server
A shared memory device that controls the shared memory buffers used in a
given Shared Memory Protocol channel.
Shared Memory Protocol
A communications protocol that uses a block of memory that is accessible to
both client and server. The memory block operates as a message buffer for
communications.
Slot 0 Controller
See Slot 0 Module. Also see Resource Manager.
Slot 0 Module
A VXIbus device that provides the minimum VXIbus slot 0 services to slots
1 through 12 (CLK10 and the module identity lines), but that may provide
other services such as CLK100, SYNC100, STARBUS, and trigger control.
SMP
See Shared Memory Protocol.
STARX
Two (2) bi-directional, 50 W, differential ECL lines that provide for
inter-module asynchronous communication. These pairs of timed and
matched delay lines connect slot 0 and each of slots 1 through 12 in a
mainframe. The delay between slots is less than 5 ns, and the lines are well
matched for timing skew.
STARY
Two (2) bi-directional, 50 W, differential ECL lines that provide for
inter-module asynchronous communication. These pairs of timed and
matched delay lines connect slot 0 and each of slots 1 through 12 in a
mainframe. The delay between slots is less than 5 ns, and the lines are well
matched for timing skew.
STST
STart/STop protocol; used to synchronize modules.
SYNC100
A Slot 0 signal that is used to synchronize multiple devices with respect to a
given rising edge of CLK100. These signals are individually buffered and
matched to less than 2 ns of skew.
Synchronous Communications
A communications system that follows the “command-response” cycle
Glossary–6
VX4380 256-Crosspoint Relay Matrix Module User Manual
Glossary
model. In this model, a device issues a command to another device; the
second device executes the command; then returns a response. Synchronous
commands are executed in the order received.
SYSFAIL*
A signal line on the VMEbus that is used to indicate a failure by a device.
The device that fails asserts this line.
System Clock Driver
A functional module that provides a 16 MHz timing signal on the Utility
Bus.
System Hierarchy
The tree structure of the commander/servant relationships of all devices in
the system at a given time. In the VXIbus structure, each servant has a
commander. A commander may also have a commander.
Test Monitor
An executive routine that is responsible for executing the self tests, storing
any errors in the ID-ROM, and reporting such errors to the Resource
Manager.
Test Program
A program, executed on the system controller, that controls the execution of
tests within the test system.
Test System
A collection of hardware and software modules that operate in concert to test
a target DUT.
TTLTRG
Open collector TTL lines used for inter-module timing and communication.
VXIbus Subsystem
One mainframe with modules installed. The installed modules include one
module that performs slot 0 functions and a given complement of instrument
modules. The subsystem may also include a Resource Manager.
Word Serial Protocol
A VXIbus word oriented, bi-directional, serial protocol for communications
between message-based devices (that is, devices that include communication
registers in addition to configuration registers).
Word Serial Communications
Inter-device communications using the Word Serial Protocol.
WSP
See Word Serial Protocol.
10-MHz Clock
A 10 MHz, ±100 ppm timing reference. Also see CLK10.
VX4380 256-Crosspoint Relay Matrix Module User Manual
Glossary–7
Glossary
488-To-VXIbus Interface
A message based device that provides for communication between the
IEEE-488 bus and VXIbus instrument modules.
Glossary–8
VX4380 256-Crosspoint Relay Matrix Module User Manual
Index
A
Accessories, 1-5
ARM, 3-16
C
*CLS, 3-53
command, 3-18, 3-22, 3-23, 3-26, 3-30, 3-35,
3-36, 3-37, 3-41, 3-45, 3-49
Command Descriptions
ARM, 3-16
command, 3-18, 3-22, 3-23, 3-26, 3-30, 3-35,
3-36, 3-37, 3-41, 3-45, 3-49
command error messages, 4-6
Command Syntax, 3-1
Syntax Example, 3-3
Commands. individual command names
Configuration Registers, 2-3
D
device dependent error messages, 4-8
E
error messages, 4-6
command errors, 4-6
device dependent errors, 4-8
execution errors, 4-7
*ESE, 3-53, 4-4
*ESE?, 3-53, 4-4
*ESR?, 3-53, 4-3
Event handling, 4-1
Event Reporting Process, 4-5
Event Reporting System, 4-1
Event Status Enable Register, 4-4
execution error messages, 4-7
F
Fast Handshake Mode, 2-3
Fuses, 1-4, 1-5
*IDN?, 3-54
*OPC, 3-55
*OPC?, 3-55
*RST, 3-55
*SRE, 3-56
*SRE?, 3-56
*STB?, 3-57
*TST?, 3-58, 3-59
*WAI, 3-59
*ESE?, 3-53
IEEEĆ488 Address, 1-7
M
Maintenance, Preventive, D-1
Message, Handling, 4-1
messages. error messages
N
Normal Transfer Mode, 2-2
O
*OPC, 3-55
OPC bit, 4-3
*OPC?, 3-55
Output queue, 4-4
Q
Queue
Output, 4-4
System Error and Event, 4-4
R
Register
Event Status Enable, 4-4
Service Request Enable, 4-2
Standard Event Status, 4-3
Status Byte, 4-1
Replaceable Parts, E-1
*RST, 3-55
I
*IDN?, 3-54
IEEE 488.2 Commands
*CLS, 3-53
*ESE, 3-53
*ESR?, 3-53
VX4380 256-Crosspoint Relay Matrix Module User Manual
S
Service Request Enable Register, 4-2
Specifications, A-1
*SRE, 3-56, 4-2
Index–1
Index
*SRE?, 3-56, 4-2
Standard Event Status Register, 4-3
Status, 4-1
Status and Event Reporting Process, 4-5
Status and Event Reporting System, 4-1
Status Byte Register, 4-1
*STB?, 3-57, 4-1
Switches, 1-5
Logical Address Switches, 1-7, 1-8
SYSFAIL*, 1-13
System Error and Event queue, 4-4
SYSTem:ERROr?, 4-4
Index–2
T
Troubleshooting the VX4380, D-1
*TST?, 3-58, 3-59
W
*WAI, 3-59
VX4380 256-Crosspoint Relay Matrix Module User Manual
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