MAUI Oscilloscopes Remote Control Manual And Automation

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Oscilloscopes
Remote Control and
Automation Manual
MAUI Oscilloscopes Remote Control and Automation Manual
© 2017 Teledyne LeCroy, Inc. All rights reserved.
Unauthorized duplication of Teledyne LeCroy documentation materials other than for internal sales and
distribution purposes is strictly prohibited. However, clients are encouraged to duplicate and distribute Teledyne
LeCroy documentation for their own internal educational purposes.
Teledyne LeCroy is a trademark of Teledyne LeCroy, Inc. Other product or brand names are trademarks or
requested trademarks of their respective holders. Information in this publication supersedes all earlier versions.
Specifications are subject to change without notice.
925131 Rev A
January 2017
Resources
Resources
Teledyne LeCroy provides many free resources to help you receive the greatest value from your
instrument. Most of the software and documentation mentioned in this manual can be downloaded from
our website; links are provided to other sites where relevant. In addition, many manuals and code
examples for further reference are installed when you install our software.
Software
Download software from: teledynelecroy.com/support/softwaredownload.
Under Oscilloscope Downloads, click the link to Software Utilities and browse the list of tools.
Manuals
Download manuals, application notes, and lab briefs from: teledynelecroy.com/support/techlib.
Use the sidebar at the left of the page to select the document category, then browse the list of links.
Technical Support
Registered users can contact their local Teledyne LeCroy service center at the number listed on our
website.
You can also submit Technical Support requests via the website at:
teledynelecroy.com/support/techhelp
Select the oscilloscope model you are using and the category into which your question falls.
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MAUI Oscilloscopes Remote Control and Automation Manual
Notational Conventions
Notational Symbols
Commands shown in this reference make use of the following notational symbols:
Symbol Function Example
< > Encloses header paths or placeholders <channel>:VOLT_DIV <v_gain>
:= Separates a placeholder from a description of the
type and range of values that may replace it
<v_gain> := 5.0 mV to 2.5 V
{ } Encloses required values, one of which must be used
in the command
TRMD {SINGLE, AUTO, NORM, STOP}
[ ] Encloses optional values
Indicates the items to its left or right can be repeated
any number of times
Sources
The character xis used to denote the greatest number of an oscilloscope object, such as input channels
or math function traces, supported by your instrument. Thus, on a two-channel oscilloscope, C1 through
Cxshould be taken to mean C1 and C2, whereas on an eight-channel oscilloscope, C1 through C8, and so
forth.
The following characters may be used wherever a <source> is indicated:
Object Mnemonic Note
Channels C1, C2, C3, C4,....Cx
Math Functions F1, F2, F3, F4,....Fx,
TA, TB, TC, TD
Math trace names TA, TB, TC, and TD used on legacy
LeCroy instruments have been replaced by F1, F2, F3 and
F4, respectively. Existing programs that utilize the old trace
names will work with MAUI oscilloscopes, but these mne-
monics are not returned in query responses. Instead, the
query will return the corresponding F1, F2, F3, and F4.
User-Defined
Parameters
P1,....Px
CUST1, CUST2, CUST3, CUST4,
CUST5
Parameter names CUST1 through CUST5 used on legacy
LeCroy instruments have been replaced by P1, etc. As with
math traces, these mnemonics may be used in programs
but are not returned by queries.
Memories M1,...Mx
ii
Notational Conventions
Units and Multipliers
Numeric values can be expressed as numeric fixed point or exponential. Units may be expressed using the
following mnemonics.
Mnemonic Unit
AAmperes
CEL Degrees Celsius
C Coulombs
DAY Days
DB Decibels
DBC Decibels Referred to Carrier
DBM Decibel Milliwatts
DBV Decibel Volts
DBUZ Decibel Microamps
DEC Decades
DEG Degrees of Arc
DIV Divisions
EVENTS Events
F Farads
FAR Degrees Fahrenheit
FT Feet
G Grams
H Henrys
HOUR Hours of Time
HZ Hertz
IN Inches
J Joules
KDegrees Kelvin
L Liters
M Meters
MIN Minutes of Time
MNT Minutes of Arc
OHM Ohms
PAL Pascals
PCT Percent
POISE Poise
PPM Parts per Million
N Newtons
RAD Radians
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MAUI Oscilloscopes Remote Control and Automation Manual
Mnemonic Unit
S* Seconds of Time / Samples
SAMPLE Samples
SEC Seconds of Arc
SIE Siemens
SWEEP Sweeps
T Teslas
UI Unit Intervals
V Volts
VA Volt Amps
W Watts
WB Webers
Units can be prefixed with multipliers modifying the value of the numeric expression. The following table of
multipliers is recognized:
Mnemonic Multiplier Exponential
Notation
E Exa- 1E18
T Tera- 1E12
M / m * Mega- / milli- 1E6 / 1E-3
n nano- 1E-9
f femto- 1E-15
P Peta- 1E15
G Giga- 1E9
k kilo- 1E3
u micro- 1E-6
p pico- 1E-12
a atto- 1E-18
Note: * While usually case doesn't matter when specifying units, as the system assumes certain
units based on the type of waveform or measurement, in some instances case will change the
meaning of the mnemonic and may or may not be accepted. Follow standard IEEE practice for
denoting units of measure.
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Part 1: Making the Remote Connection
Part 1: Making the Remote Connection
You can fully control your instrument remotely using either:
lCOM Automation commands
lIEEE 488.2 General Purpose Interface Bus (GPIB) commands
The remote connection can be made over a variety of physical interfaces such as ENET, GPIB, LSIB, or
USBTMC, using several interface drivers and protocols.
This section describes the software tools for remote control and procedures for making the remote
connection from a controller to an oscilloscope.
Understanding Remote Control Layers 1-2
Software Tools for Remote Control 1-3
Connecting via ENET 1-5
Connecting via USBTMC 1-9
Connecting via GPIB 1-10
Connecting via LSIB 1-11
Configuring DCOM Connections 1-12
Testing the Remote Connection 1-20
Remote Control Assistant 1-21
ActiveDSO 1-22
VISA 1-25
WaveStudio 1-28
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MAUI Oscilloscopes Remote Control and Automation Manual
Understanding Remote Control Layers
It is helpful to understand some high-level concepts regarding how the oscilloscope is operated through
remote control and the terminology employed throughout this section.
From bottom to top, the components interact in the following manner:
The cable is the physical conduit between the controller (usually a PC) and the oscilloscope, connected on
either end to the hardware interface. Interfaces vary based on oscilloscope model and include ENET
(often labeled LAN on the oscilloscope), USBTMC, GPIB, and LSIB.
Depending on the interface selected, you may require a PC adapter in order to connect the cable. This is
particularly true for LSIB and GPIB. ENET ports are typically standard and do not require special adapters.
The oscilloscope may also require an oscilloscope adapter to make the connection.
Different protocols can be used for transmitting messages between the controller and the oscilloscope.
This selection again depends on the hardware interface. Available protocols include VICP (based on
TCP/IP), VXI-11 (for the LXI standard), USBTMC, GPIB, and LSIB.
PC instrument drivers are programs that enable the controller to interface with the oscilloscope, such as
ActiveDSO, VISA drivers, IVI drivers and LabVIEW drivers. They are the software complement to the
hardware interface. These programs do the work of encapsulating your programs messages into the
requisite interface messages that manage the exchange between device and controller.
The oscilloscope Remote Control Manager includes the drivers needed to make the software interface
from the oscilloscope side. Teledyne LeCroy oscilloscopes are shipped with everything necessary for
remote control functionality pre-installed. All you have to do to is select which protocol you want to use for
remote control from the instrument's Remote dialog.
The oscilloscope application (XStream) is the program that displays, transforms, and measures digitized
input signals and enables you to control the instrument. It is also the program that exchanges information
with the PC applications over the remote connection.
PC applications are programs residing on the controller that exchange data with the oscilloscope
application or function as a remote command console, such as WaveStudio, LabVIEW, MATLAB, and
custom applications.
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Part 1: Making the Remote Connection
Software Tools for Remote Control
Many free software tools are available to help you make and manage the remote connection. See
Resources for download information. This software is to be installed on the PC/controller. Teledyne
LeCroy oscilloscopes are pre-installed with all necessary software for remote control.
Interface Drivers
ActiveDSO
Based on Microsoft's ActiveX technology, ActiveDSO simplifies programming for Teledyne LeCroy
oscilloscopes within the Microsoft environment. ActiveDSO provides interface drivers and a client library
to make the remote connection over ENET, GPIB or USBTMC interfaces. It also supports many
Automation features besides remote control. See ActiveDSO.
VISA
VISA-compliant drivers also provide the necessary software interface for remote control over ENET, GPIB,
or USBTMC. Add-on tools like NI-VISA handle device communications for many programming languages,
such as C++, LabVIEW, and Python. An installation of NI-VISA (or a VISA driver that behaves exactly like it)
is required if you cannot use ActiveX technologies such as ActiveDSO or WaveStudio. NI-VISA is always
required if you are uisng the USBTMC interface for remote control.
LeCroy VICP Passport and VICP Client Library
The VICP Passport was developed specifically for those using NI-VISA with the Teledyne LeCroy VICP
protocol. It provides the requisite VISA Passport functions for VICP communications.
Not technically a driver, the VICP Client Library provides the necessary toolkit for developing a VICP
interface to the oscilloscope from machines that are not running Windows.
LeCroyScope IVI Driver
The VISA-based LeCroyScope IVI Driver is an Interchangeable Virtual Instrument technology that provides
a standard API for communication with instruments. Provided to meet LXI standard requirements, the
driver strictly adheres to the IVI-Scope instrument class and includes both IVI-C and IVI-COM drivers. See
Introducing the LXI Interface for instructions on using the driver.
Note: Although provided for LXI compliance, you can use the IVI Driver even if your remote control
setting is TCP/IP (VICP), rather than LXI (VXI-11).
LabVIEW Drivers
The LeCroy_Wave_Series driver, created using the LabVIEW project architecture, is available for Windows
users who wish to control their oscilloscope through a LabVIEW™ program. The lcwave driver, an llb
LabView library, is available for those using pre-Windows oscilloscope models. Both drivers can be used
over an ENET, GPIB, or USBTMC connection. See Lab Brief WM832: Getting Started with the "lcwave" and
"LeCroy Wave Series" LabVIEW Drivers for instructions.
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MAUI Oscilloscopes Remote Control and Automation Manual
Connectivity Tools
XStreamBrowser
The XStreamBrowser utility enables you to view, copy, and modify the COM object hierarchy of the
connected oscilloscope application. See XStreamBrowser.
WaveStudio
For PCs running Windows 10, 7, VISTA, or XP, WaveStudio is a remote control console that provides a
graphical user interface for oscilloscope setup, waveform inspection, and data transfer. It supports TCPIP,
LXI, GPIB, LSIB, or USBTMC/USB488 connections. See WaveStudio.
ScopeExplorer
For PCs running Windows 2000 or XP, ScopeExplorer is a connectivity tool that interfaces legacy model
Teledyne LeCroy oscilloscopes (e.g., LCxxx, LTxxx, 93xx) to the Windows desktop.
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Part 1: Making the Remote Connection
Connecting via ENET
Teledyne LeCroy oscilloscopes employ a standard Ethernet interface for utilizing the TCP/IP transport
layer.
Hardware
For purposes of remote control, you may either:
lConnect the oscilloscope to a LAN port or hub using a straight Ethernet cable
lConnect the oscilloscope directly to the controller using a crossover cable
Tip: If you are concerned mainly with system throughput, a LAN connection is not recommended
as network traffic may slow down oscilloscope data transfer rates. Use a direct connection, or
consider using LSIB if your oscilloscope supports it.
IPAddress
The oscilloscope accepts DHCP addressing. Be sure the controller and the oscilloscope are on the same
subnet.
If connected via LAN, you may optionally assign a static IP address to the oscilloscope. You must assign a
static IP address if using a crossover cable to connect.
Tip: Use the standard Windows networking dialogs to set the instrument IP address. To access
the Windows control panel, choose File > Minimize or go to Utilities > Utilities Setup > Remote
and select Net Connections.
If both controller and oscilloscope are connected to a name server, you may use the <hostname> string for
addressing. The <hostname> string must be the instrument name that is recognizable to the name server.
Protocol Selection
There are two protocol options for remote control via ENET:
lVICP, for which you select the TCP/IP remote control setting
lVXI-11, for which you select the LXI remote control setting
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MAUI Oscilloscopes Remote Control and Automation Manual
Connecting with VICP
The TCP/IP (VICP) remote control setting uses port 1861 and the proprietary VICP protocol for
transmitting messages.
Note: LabVIEW programmers should use the TCP/IP (VICP) setting with an installation of NI-VISA
and VICP Passport to communicate with Teledyne LeCroy oscilloscopes.
Controller Set Up
Open port 1861 on the controller for TCP/IP communications.
If the controller runs Windows, install NI-VISA to manage the interface functions of the VICP connection.
NI-VISA users should also install the VICP Passport.
Those who are not running Windows should install the LeCroyVICP Client Library. This library can be
downloaded free of charge from www.SourceForge.net. You will need to use the library to program your
own VICP interface.
If you are running Windows and can utilize ActiveX controls, we highly recommend installing ActiveDSO on
the controller to simplify communications with the oscilloscope.
Optionally, install the LeCroyScope IVI driver or a LabVIEW driver.
Oscilloscope Set Up
Go to Utilities > Utilities Setup > Remote and choose TCP/IP (VICP).
Note the instrument's IP address for use in VISA resource strings and function calls.
VICP Protocol
VICP is the Versatile Instrument Control Protocol, the proprietary protocol used by the TCP/IP (VICP)
remote control setting on Teledyne LeCroy oscilloscopes. This protocol aims to emulate IEEE488.2 and
includes operation bits corresponding to SRQ, EOI, Clear, and others in a header that is defined by the VICP
protocol.
VICPis registered with IANA to communications port 1861.
Code to parse VICP packets is publicly available at: http://www.SourceForge.net.
See the Application Brief LAB_WM827: Understanding VICP and the VICP Passport.
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Part 1: Making the Remote Connection
VICP Headers
The format of the header sent before each data block of a VICP transmission, both to and from the
instrument, is set out in the following table:
Byte Number Purpose
0 Operation
1 Header Version
2 Sequence Number*
3 Spare (reserved for future expansion)
4 Block Length, (bytes of data), MSB
5 Block Length (bytes of data)
6 Block Length (bytes of data)
7 Block Length, (bytes of data), LSB
* The sequence number is used to synchronize write/read operations to simulate 488.2 “discard unread response
behavior. Valid range is 1 to 255 (zero is omitted intentionally).
VICP Operation Bits
Operation bits are as follows:
Data Bit Mnemonic Purpose
D7 DATA Data block (D0 indicates termination with/without EOI)
D6 REMOTE Remote Mode
D5 LOCKOUT Local Lockout (Lock out front panel)
D4 CLEAR Device Clear (if sent with data, clear occurs before data block is passed to parser)
D3 SRQ SRQ (Device to PC only)
D2 SERIAL POLL Request a serial poll
D1 Reserved Reserved for future expansion
D0 EOI Block terminated in EOI
Logic 1 = use EOI terminator
Logic 0 = no EOI terminator
VISA Addressing
Code strings such as "TCPIP0::<IP address>::1861::SOCKET" may or may not work when using VICP
depending on how the application handles instrument responses. The data returned will include header
information that needs to be parsed, and allowances must be made to trap situations where a transfer is
not complete, or where there is an unread response from the instrument. SOCKET connections should
work properly if you are using the VICP Client Library.
Teledyne LeCroy developed the VICP Passport to handle socket connections more reliably when using NI-
VISA. Instead of "TCPIP::<IP address> . . .", use "VICP::<IP address>" to make the connection.
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MAUI Oscilloscopes Remote Control and Automation Manual
Connecting With VXI-11
LXI is an industry-standard specification for LAN-based instruments that utilizes the VXI-11 protocol for
TCP/IP communications and instrument discovery. For information, visit www.lxistandard.org.
Teledyne LeCroy oscilloscopes are LXI Class-C compliant. We have implemented a full-featured stack that
allows any command or query to be sent using the VXI-11 protocol, beyond the LXI requirements for
discovery and execution of simple *IDN? queries.
Note: You can use the VXI-11 protocol for remote control of Teledyne LeCroy oscilloscopes even if
your network is not LXI compliant. For those who cannot utilize ActiveX or VICP, LXI (VXI-11) is the
best remote control setting.
Resources
The LXI specification stipulates that vendors supply:
lAn IVI driver for the instrument. Download and install the LeCroyScope IVI driver if you wish to
implement the IVIstandard API. See Resources.
Note: An IVI driver is required to connect to MATLAB applications using LXI (VXI-11).
lA web server to simplify remote control configuration. To access this page from the controlling PC,
enter the oscilloscope IP address in URL field of a browser.
Controller Setup
Install NI-VISA to manage the interface functions of the underlying TCP/IP connection.
If you are running Windows and can utilize ActiveX controls, we highly recommend installing ActiveDSO on
the controller to simplify communications with the oscilloscope.
Optionally, install the LeCroyScope IVI driver or LabVIEW driver.
Oscilloscope Setup
Go to Utilities > Utilities Setup > Remote and choose LXI (VXI-11).
We recommend that you modify the password for LAN access. The default username is lxi.lecroyuser
and password is lxi. You can reset to these defaults by pressing LAN Configuration Reset.
Note the instrument's IP address for use in VISA resource strings and function calls.
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Part 1: Making the Remote Connection
Connecting via USBTMC
USBTMC is a protocol built on top of USB that allows GPIB-like communication with USB devices. The
USBTMC protocol supports service requests, triggers, and other GPIB-specific operations.
Some (not all) MAUI oscilloscopes offer a USBTMC remote control setting. Check your product datasheet
to confirm if this is supported.
Hardware
Connect a USB A-B cable from any host port on the controller to the device port on the oscilloscope, which
is usually specifically marked USBTMC.
Controller Set Up
Install NI-VISA v 3.0 or later on the controller PC.
Note: NI-VISA is always required for the USBTMCconnection.
If you are running Windows and can utilize ActiveX controls, we highly recommend installing ActiveDSO on
the controller to simplify communications with the oscilloscope.
Optionally, install a LabVIEW driver.
Oscilloscope Set Up
Go to Utilities > Utilities Setup > Remote and select the USBTMC remote control setting.
Note the USBTMC VISA Address for use in VISA resource strings.
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MAUI Oscilloscopes Remote Control and Automation Manual
Connecting via GPIB
The IEEE 488.2 General Purpose Interface Bus, or GPIB, interconnects independent devices by means of a
cable bus. Although largely replaced by other serial buses, Teledyne LeCroy's IEEE 488.2 command set is
still supported by all MAUI oscilloscopes. See the IEEE 488.2 Command Reference.
GPIB is offered as an optional, factory-installed interface on most MAUI oscilloscopes over 350 MHz
bandwidth. You can send Automation commands over the GPIB interface using the VBS command, it is
not restricted to the IEEE 488.2 commands.
Caution: Do not install third-party GPIB driver software on Teledyne LeCroy oscilloscopes; this can
result in a non-functional GPIB interface. The only GPIBdriver designed to operate on the
instrument is included with your oscilloscope's firmware.
The optional USB2-GPIB Converter enables you to take advantage of high-speed transfer from the
oscilloscope using the USB2 interface on newer MAUI oscilloscopes. However, this is still treated as a
GPIB connection in VISA resource strings. See the USB2-GPIB Converter User's Manual.
Hardware
If both controller and oscilloscope have a GPIB port, connect them using a GPIB cable.
If using the USB2-GPIB Converter, connect the converter from the GPIB port on the controller to a USB2
port on the oscilloscope. On the first connection, accept and install the device driver. The driver is located
at: C:\Program files\LeCroy\XStream\Drivers_X86(or X64)\GPIB2USB. The installer is called dpinst.exe.
Reboot the instruments.
Controller Set Up
Install NI-VISA to manage the interface functions of the GPIB connection.
If you are running Windows and can utilize ActiveX controls, we highly recommend installing ActiveDSO on
the controller to simplify communications with the oscilloscope.
Optionally, install a LabVIEW driver.
Oscilloscope Set Up
On the oscilloscope, go to Utilities > Utilities Setup > Remote and select the GPIB option. If necessary,
modify the oscilloscope's GPIB Address.
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Part 1: Making the Remote Connection
Connecting via LSIB
The LeCroy Serial Interface Bus, or LSIB, is a proprietary standard for high-speed data transfer from the
oscilloscope with speeds up to 325 MB/s. Teledyne LeCroy’s exclusive LSIB solution is based on the wired
PCI Express standard that uses a 4-lane bus for remote data transfer. An LSIB API is published.
While LSIB offers significant improvements in data transfer rate over 100Base-T ENET, USBTMC, and
GPIB, the LSIB API is geared toward waveform and data transfer and does not provide for many other
common remote control functions such as remote set up, "hardcopy" screen capture, etc.
LSIB is an optional, factory-installed interface on WavePro, WaveMaster, and LabMaster series
oscilloscopes.
Hardware
Install the LSIB host board or host card on the controller PC, then connect the controller to the
oscilloscope using the LSIB cable.
See the LSIB Host Interfaces Operator's Manual for instructions on making the LSIB connection.
Controller Set Up
Run the LSIB installer for Windows or Linux on the controller. After installation, the online LSIB API (LSIB-
API-Ref-OLH-E.chm), can be found in:
C:\Program Files\LeCroy\XStream\LSIB\Docs
Oscilloscope Set Up
On the oscilloscope, go to Utilities > Utilities Setup > Remote and select the LSIB remote control option.
Shut down both the oscilloscope and the controller. Restart the oscilloscope first, followed by the
controller. You do not have to wait for the oscilloscope's boot cycle to complete to restart the controller.
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MAUI Oscilloscopes Remote Control and Automation Manual
Configuring DCOM Connections
The Windows Distributed Component Object Model (DCOM) permits the distribution of different
components of a single application across two or more networked computers and the remote display and
control of applications. Accessing a networked oscilloscope remotely via DCOM is equivalent to logging on
to the oscilloscope itself and executing programs "locally."
In order to access the oscilloscope's object hierarchy without ActiveDSO or a VISA driver, or to use
XStreamBrowser remotely, Windows DCOM settings must be configured to permit the controller and
oscilloscope to control applications residing on the other.
Note: DCOM is pre-configured on WaveSurfer 3000 oscilloscopes, which run the Windows CE
platform and do not allow access to a desktop. Install the WaveStudio software, which displays the
COM hierarchy of a connected device when Automation Browser is selected.
To complete this process, you will:
1. Configure the remote PC to permit DCOM connections.
2. Configure the oscilloscope DCOM settings, including creating user accounts (if required).
3. Test the connection.
Note: You must have Administrator privileges on both the PC and the oscilloscope to complete
DCOM configuration.
A. Determine Windows OS
If you do not know the operating system running on the controller or the oscilloscope, go to the Windows
desktop, right-click on the My Computer icon and choose Properties. Follow the procedures below
indicated for your operating system.
B. Determine Network Domain and User Accounts
If the oscilloscope is not on the same NT domain as the controller PC, you will need to set up an account
for the PC user in the oscilloscope domain using the exact same user name and password as on the PC.
That same user must also be allowed into the oscilloscope DCOM section. Before proceeding, consult
your Network Administrator regarding your network configuration.
If the machines are on different domains, verify the user name and password for each user account that
will be used to send Automation commands to the oscilloscope. You will need this information to complete
the configuration on the oscilloscope.
C. Install XStreamBrowser
Download and install the XStreamBrowser on the controller PC.
Note: XStreamBrowser is installed by default on the oscilloscope.
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Part 1: Making the Remote Connection
D. Configure Component Services
Windows 7 and 10
On the Controller
Follow these steps if the PC is running the Windows 7 or Windows 10 operating system.
1. Go to the Windows Start menu and type dcomcnfg.exe in Search programs and files.
2. Expand Component Services until you see My Computer. Right-click on My Computer and choose
Properties.
3. On the Options tab, enter 0for Transaction timeout, then click Apply.
4. Open the Default Properties tab. Make sure Enable distributed COM on this computer is
checked. If not check it and click Apply.
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MAUI Oscilloscopes Remote Control and Automation Manual
On the Oscilloscope
All Zi series, HDO series, MDAs, WaveRunner 8000s, and HROs use the 64-bit Windows 7 platform.
We recommend connecting a keyboard and mouse to the oscilloscope before beginning this procedure.
Use any USB ports.
Create Users
1. Choose File > Minimize to display the Windows desktop.
2. Windows 7: Go to Start >Control Panel >User Accounts >Manage User Accounts.
Windows 10: Go to Start >Settings >Accounts >Other People.
3. For each user that is to access the oscilloscope remotely, Add a user ("Another work or family user")
with the same user name and password as on the PC. Be sure the user is created as a Local
Administrator.
Configure DCOM Settings
1. Go to the Windows Start menu and enter dcomcnfg.exe in Search programs and files.
2. Expand Component Services until you see My Computer. Right-click on My Computer and choose
Properties.
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Part 1: Making the Remote Connection
3. On the Options tab, enter 0for Transaction timeout, then click Apply.
4. Open the Default Properties tab. Make sure Enable distributed COM on this computer is
checked. If not check it and click Apply. Close the dialog when done.
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MAUI Oscilloscopes Remote Control and Automation Manual
5. On the Component Services window, navigate to Component Services >Computers >My
Computer >DCOM Config and select it.
6. From the list on the right, right-click on LeCroyXStreamDSO and choose Properties.
7. On the Properties dialog, open the Identity tab and select The interactve user.Apply and close
Properties and Component Services.
Open Firewall
1. Go to the Windows Start menu and enter wf.msc in Search programs and files.
2. Open Inbound Rules. For both Inbound rules named Windows Management Instrumentation
(DCOM-In), right-click and choose Enable Rule. Close Windows Firewall dialog.
3. Choose Start >Shutdown >Log Off, then log back in as the new user that was created on the
oscilloscope.
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Part 1: Making the Remote Connection
Windows XP or Vista
On the Controller
Follow these steps if the controller PC is running Windows XP or Vista operating system.
1. Go to Start > Run, enter dcomcnfg.exe and click OK.
Note: If Run is not in your Start menu, open a terminal and run dcomcnfg.exe.
2. Expand Component Services > Computers.
3. If you see a Windows Security Alert pop-up, click Unblock.
4. In the Computers folder, right-click My Computer and choose Properties.
5. On the Properties dialog, open the Options tab and change Transaction Timeout to 0. Click Apply.
On the Oscilloscope
Follow these steps if your legacy model LeCroy oscilloscope is still running Windows XP or Vista operating
system.
Contact Technical Support for assistance if your oscilloscope is running Windows XP Embedded.
Open Firewall
1. Go to Start > Control Panel > Firewall. For Vista machines, click Change Settings.
2. On the Windows Firewall dialog, open the Exceptions tab.
3. Select LeCroyXStreamDSO Main Application.
4. Click Add Port.
5. On the Add Port dialog, make the following settings, then click OK:
lName: DCOM
lPort number: 135
lTCP: selected
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MAUI Oscilloscopes Remote Control and Automation Manual
Turn Off Simple File Sharing
This procedure is required only for Windows XP and Vista oscilloscopes that are on the same NT domain as
the controller.
1. Go to Start > Control Panel > Folder Options.
2. On the Folder Options dialog, open the View tab and clear the checkbox Use simple file sharing.
3. Click OK.
Create Users
If the oscilloscope is on the same NT domain as the controller, you can skip this procedure.
If the oscilloscope is not on the same NT domain as the controller, each PC user that is to send
Automation commands to the oscilloscope must have a corresponding user account on the oscilloscope,
configured with the identical user name and password. Both accounts must have Administrator privileges.
1. On the Windows desktop, right-click on My Computer and choose Manage.
2. Expand the hierarchy to display Local Users and Groups > Users. Select Users
3. Right-click on a blank area of the dialog and choose New User.
4. Enter the User name and Password exactly as they appear on the controller PC. Confirm password.
5. Deselect User must change password at next logon.
6. Click Close.
Configure DCOM Settings
1. Go to Start > Run, enter dcomcnfg.exe and click OK.
Note: If Run is not in your Start menu, open a terminal and run dcomcnfg.exe.
2. Expand Component Services.
3. If a Windows Security Alert pop-up appears, click Unblock.
4. Expand Computers, right-click on My Computer, and select Properties.
5. Open the Options tab and set the Transaction timeout to 0. Click Apply.
6. Open the Default Properties tab, select Enable Distributed COM on this computer, and choose a
Default Authentication Level of Connect.
7. Open the COM Security tab and under Launch and Activation Permission click Edit Limits.
8. On the Launch Permission dialog, click Add.
9. On the Select Users… dialog:
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Part 1: Making the Remote Connection
lIf the PC and oscilloscope are on the same NT domain, select the PC user account.
lIf the PC and oscilloscope are not on the same NT domain, enter the PC user account name
and click Check Names.
Click OK.
10. On the Launch Permissions dialog, check Allow for all permissions. Click OK.
11. On the Component Services window, expand My Computer > DCOM Config. Right-click on
LeCroyXStreamDSO and choose Properties.
12. Open the Identity tab and select The interactive user.
13. Open the Security tab, under Launch and Activation Permissions select Customize, then click Edit.
14. On the Select Users… dialog:
lIf the PC and oscilloscope are on the same NT domain, select the PC user account.
lIf the PC and oscilloscope are not on the same NT domain, enter the PC user account name
and click Check Names.
Click OK.
15. On the Launch Permissions dialog, check Allow for all permissions. Click OK.
16. On the Security tab, under Access Permissions, select Customize and click Edit. Repeat Steps 14
and 15.
17. Choose Start > Shut Down > Restart to reboot the oscilloscope.
Testing the DCOM Connection
Install the XStreamBrowser on the PC and use it to Connect to Remote Instrument (DCOM).
If the connection is properly configured, you should now see the oscilloscope application object hierarchy
appear in the XStreamBrowser window.
Note: WaveSurfer 3000 users should instead install the WaveStudio software, which will display
the COM hierarchy of a connected device when Automation Browser is selected.
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MAUI Oscilloscopes Remote Control and Automation Manual
Testing the Remote Connection
Once you have completed all the steps required to make the remote connection to your oscilloscope, test
that you can "see" it from the controller and send remote commands.
Using WaveStudio
The free WaveStudio software is capable of testing several types of remote connection as well as serving
as a remote command terminal for controlling the oscilloscope. A trial copy is installed on the oscilloscope,
and another may be installed on Windows-based PCs. For download information, see Resources.
Follow these steps to test the connection:
1. Click the Add Scope button on My Scope Explorer or the Scope menu ribbon.
2. On the Add Device dialog, select the remote connection type.
3. Enter the oscilloscope's network name or address and click OK.
If the oscilloscope is found, an entry is added to the My Scope Explorer window. The status should indicate
the device is "Alive." This confirms the connection is working.
If the oscilloscope is found but cannot be connected, after a brief time out an entry is added to My Scope
Explorer indicating the selected device is "Dead." Check the address and physical connection again. If you
still cannot connect, consult with your Network Administrator.
Using the PING Command
For LAN users, both the physical cable connection and proper host TCP/IP configuration can be verified
using the Ping command.
Note: PING is a good way to check the network connection, but it doesn't guarantee the socket
connection to the oscilloscope at port 1861. Connecting via WaveStudio or XStreamBrowser is a
better test.
At an MS-DOS prompt, type:
ping <IP_address>
where <IP_address> is the address assigned to the oscilloscope.
The Command Prompt window shows an exchange similar to that below if the Ping is successful. The
Ethernet connection is shown as established and the ping command has sent a message to the
instrument and waited for a response. If a timeout occurs, the IP address used for the destination (the
oscilloscope) is incorrect or not within the subnet mask of the host's IP.
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Part 1: Making the Remote Connection
Successful ping showing reply.
Remote Control Assistant
The Remote Control Assistant (RCA) feature of MAUI oscilloscopes maintains a log of remote control
commands received and responses issued (which would include Automation controls sent within the VBS
command), allowing the programmer to receive feedback on errors in his or her source code.
The RCA has several modes of operation: Off, Errors Only, and Full Dialog.
lIn Errors Only mode (the default), the RCA will keep a log of any mistakes in the commands
received, and display the error detected.
lIn Full Dialog mode, all commands and responses are logged.
This selection can be made by going to Utilities > Utilities Setup > Remote on the oscilloscope.
Touch Show Remote Control Log on the Remote dialog to pop up a window showing the log file. From
there you can clear the log or save it as a text file.
The RCA can also be set by using the remote commands COMM_HELP (CHLP) and
COMM_HELP_LOG (CHL).
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MAUI Oscilloscopes Remote Control and Automation Manual
ActiveDSO
ActiveDSO is a proprietary ActiveX™ control that enables Teledyne LeCroy oscilloscopes to be controlled
by and exchange data with a variety of Windows applications that support the ActiveX standard. Microsoft
Office suite, Internet Explorer, Visual Basic, Visual C++, and Visual Java are a few of the many applications
and languages that support ActiveX controls.
ActiveDSO hides the intricacies of programming in ActiveX and provides a simple and consistent interface
to the controlling application. The ActiveDSO control may be used as either:
lAn "invisible" object accessed via a scripting language, for example, VBS.
lA visible object embedded in an OLE Automation compatible client, such as a VBA macro launched
by a Windows application button.
Note: Many of our Automation examples utilize Visual Basic Script (VBS) as the "built in"
Automation language, as it is syntactically identical to our LeCroy Setup Script (.LSS). Visual Basic
for Applications (VBA) is a subset of Visual Basic that makes it very easy to utilize the services of
OLE Automation Servers and ActiveX Controls as a macro "programming" language.
A great benefit of ActiveDSO is that it is completely independent of the remote hardware interface. The
connection via ENET (TCP/IP), GPIB, or USBTMC is made by a single command near the start of a
program. It may be used to send Automation commands or legacy IEEE 488.2 remote control commands.
Download the ActiveDSO software free of charge from our website (see Resources) and install ActiveDSO
on the controller PC. The driver installs with the ActiveDSO Developer's Guide.This manual documents all
the methods and properties used to program ActiveDSO objects. Following are some simple examples.
More extensive examples are installed in the ActiveDSO program folder.
Instantiating the ActiveDSO Control
The control's external name is always: LeCroy.ActiveDSOCtrl.1
The control's CLSID is 450A9897-D9C9-11D1-9966-0000F840FC5E
Following are instantiations of the control as an "invisible" object used to pass remote commands in
several commonly used languages. In each case, the control is aliased as "dso", although for this you may
substitute whatever you wish.
Language
VBA Dim dso As Object
Set dso = CreateObject("LeCroy.ActiveDSOCtrl.1")
Python import win32com.client
dso=win32com.client.Dispatch("LeCroy.ActiveDSOCtrl.1")
Visual C++ CActiveDSO dso;
RECT dummyRect;
dso.Create("LeCroy.ActiveDSOCtrl.1","HiddenWindowForDSOControl",0,dummyRect,
this,0);
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Part 1: Making the Remote Connection
ActiveDSO Methods for Remote Control
Following are several ActiveDSO methods that are particularly useful for remote control. See the
ActiveDSO Developer's Guide for an explanation of all ActiveDSO methods.
MakeConnection
This method establishes the connection from controller to oscilloscope. It is a single line of code that
requires only that you pass the oscilloscope interface and address to which to connect.
The following table shows the MakeConnection string for each remote interface type.
Interface Syntax Example
TCP/IP MakeConnection("IP: <IP address>") MakeConnection("IP: 172.25.9.22")
GPIB MakeConnection("GPIB[x]: <GPIB address>")
x:= 0 to 3 (optional)
MakeConnection("GPIB: 4")
USBTMC MakeConnection("USBTMC: <VISA resource string>") MakeConnection("USBTMC:
USB0::0x05FF::0x1023::2807N59057::INSTR")
Note: TCP/IP includes the TCP/IP (VICP) and LXI (VXI-11) remote control settings. When the VISA
resource string is used with ActiveDSO, it is preceded by a single colon space instead of the double
colon used with a VISA driver.
Disconnect
The Disconnect method disconnects the control from the device. This method performs the necessary
termination functions, which will cleanup and disconnect the interface connection.
WriteString
The WriteString method sends a command string to the connected device with or without a terminating
EOI (End or Identify). It can be used with Automation or legacy remote commands.
WriteString follows the syntax:
<controlName>.WriteString("<textString>", <EOI Boolean>)
<controlName>:= name used to instantiate the ActiveDSO control
<textString>:= command string sent to the device
<EOI Boolean>:= {1, 0}
If EOI is set to 1 (TRUE), the command terminates with EOI, and the device interprets the command right
away. This is normally the desired behavior.
If EOI is set to 0 (FALSE), a command may be sent in several parts with the device starting to interpret the
command only when it receives the final part, which should have EOI set to TRUE.
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MAUI Oscilloscopes Remote Control and Automation Manual
ReadString
The ReadString method reads a string response from the instrument and can be used to read the results
of queries.
' Read the amplitude parameter measurement, store in cell L3 of Excel worksheet
Call o.WriteString("c1:pava? ampl", 1)
Worksheets("Sheet1").Cells(3, 12).Value = o.ReadString(500)
' Read the rise time parameter measurement into variable
Call o.WriteString("c1:pava? rise", 1)
RiseTime = o.ReadString(500)
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Part 1: Making the Remote Connection
VISA
VISA refers to the Virtual Instrument Software Architecture, an API widely used in Test & Measurement for
communicating with instruments from a PC. With the installation of a VISA driver, the programmer needs
only provide a VISA resource string to create a connection to a remote instrument, and VISA passes
subsequent write or read data requests and the corresponding VISA passport to the instrument.
A VISA driver that behaves exactly like NI-VISA is required for remote connection to Teledyne LeCroy
oscilloscopes over the ENET, USBTMC, and GPIB interfaces if you cannot utilize ActiveX technology (such
as ActiveDSO and WaveStudio) on your network. Programmers should download and read the IVI VISA
specification document for their programming language to fully understand the VISA API. It is always a
good idea to install the IVI VISA API in order to decouple your Automation program from the driver used.
We have tested our instruments with National Instrument's implementation of VISA, NI-VISA, and
recommend an installation of this if you are making the remote connection from a Windows machine. NI-
VISA can be downloaded from: https://www.ni.com/visa/
Note: For NI-VISA licensing requirements and fees, see https://www.ni.com/visa/license.htm.
Unless you install NI-VISA, you will have to program your own remote control interface. We supply the VICP
Client Library for those who wish to use the VICP protocol but cannot use NI-VISA because they are not
working in the Windows environment.
VICP Passport for NI-VISA
Those using NI-VISA for VICP connections in the Windows environment should install the VICP Passport.
The passport is a plug-in DLL for NI-VISA that provides a translation layer between the standard NI-VISA
API and Teledyne LeCroy's VICP protocol. See the Application Brief LAB_WM827: Understanding VICP and
the VICP Passport for more information.
Note: NI-VISA provides the necessary VISA passports for LXI, GPIB, and USBTMC connections;
VICP Passport is only necessary if you're using VICP protocol.
Download VICP Passport from teledynelecroy.com. See Resources.
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MAUI Oscilloscopes Remote Control and Automation Manual
VISA Resource Strings
Use one of the following VISA resource strings to make the remote connection:
Protocol VISA Resource String
VICP
(TCP/IP)
VICP::<IP address>
VICP::<hostname>
Examples:
VICP::172.29.9.22
VICP::LCRY4201N10003
VXI-11
(LXI)
TCPIP::<IP address>::INSTR
TCPIP::<hostname>::INSTR
Examples:
TCPIP::172.29.9.22::INSTR
TCPIP::LCRY4201N10003::INSTR
GPIB GPIB::<GPIB address>::INSTR
Example:
GPIB::4::INSTR
USBTMC USBTMC::<manufacturer ID::model code::serial number::USB interface number>::INSTR
Example:
USBTMC::USB0::0x05FF::0x1023::2807N59057::INSTR
The suffix ::INSTR is not necessary for VICP, but those using other protocols should continue to use the full
syntax.
The <hostname> string is the name by which the DNS server knows the instrument (often the serial
number) and can be used only if the oscilloscope and controller are both connected by LAN to a name
server.
On the oscilloscope, go to Utilities > Utilities Setup > Remote to find the instrument address and serial
number.
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Part 1: Making the Remote Connection
Using VISA Aliases
For LXI (VXI-11), GPIB, and USBTMC connections, VISA aliases can be used instead of the full VISA
resource string, allowing you to decouple your remote control programs from DHCP changes or long,
cumbersome device addresses.
Note: VISA aliases cannot be used with the VICP protocol.
Tools like NI-MAX (Measurement & Automation Explorer) make it very easy to assign aliases to any device
in your system, which are automatically updated whenever the address is changed.
Once the alias is assigned, simply replace the full VISA connect string with the alias in your code. For
example, in this Python script, instead of:
import visa
rm = visa.ResourceManager()
lecroy = rm.open_resource("TCPIP0::HDO-LCRY::inst0::INSTR")
You could send:
import visa
rm = visa.ResourceManager()
lecroy = rm.open_resource("HDO6104MS")
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MAUI Oscilloscopes Remote Control and Automation Manual
WaveStudio
WaveStudio is a PC-based connectivity tool that interfaces a Teledyne LeCroy oscilloscope to a Windows
XP, Vista, 7 or 10 operating system, with support for 32- and 64-bits. It is a fast and easy way to analyze
acquired waveforms offline, or to remotely control an oscilloscope from your desktop.
Unlike XStreamBrowser, which works solely within the Windows COM architecture, WaveStudio can be
connected to a device over most of the available remote control interfaces—ENET (using TCP/IP or LXI),
GPIB, or USBTMC—making it a good way to test different remote connections.
Note: WaveStudio does not support LSIBconnections to the instrument. Choose another remote
connection if you wish to use WaveStudio for remote control.
See the WaveStudio online help or WaveStudio User's Manual for more information.
Connecting to a Device
To use WaveStudio to make the remote connection to an oscilloscope:
1. Configure both the PCrunning WaveStudio and the oscilloscope to support the remote control
method you wish to use.
2. Launch WaveStudio and click the Add Scope icon either on the Scope ribbon or at the top of
the My Scope Explorer window.
3. Select the remote control method in use.
4. Enter the oscilloscope's domain name or address, depending on the remote connection type (e.g.,
IP address for TCP/IP, GPIB address for GPIB).
5. The device should now appear in the My Scope Explorer window with a status of Alive.
If it does not appear or is not Alive, select it and click the Edit icon . Check that you have entered
the correct name or address. Change it if necessary.
Tip: Go to Utilities > Utilities Setup > Remote on the oscilloscope to check the remote
control method and the device name or address. These must match what is entered in
WaveStudio. If DHCP is in use, the address may have changed since the oscilloscope was
originally added to WaveStudio.
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Part 1: Making the Remote Connection
Sending Remote Commands
WaveStudio includes a terminal window from which you can execute IEEE 488.2 remote control
commands. Use the VBS command to send Automation commands.
1. Follow the procedure above to connect to the oscilloscope. If the device is already added to My
Scope Explorer, just select it from the list.
2. When the connection is Alive, select Terminal from the list of objects/folders belonging to the
device in My Scope Explorer.
3. At the top of the Terminal window, immediately below the words "LeCroy WaveStudio," enter the
remote command or query and Return.
Replies to queries appear in the bottom section of the Terminal window.
Automation Browser
For WaveSurfer3000 oscilloscopes, which cannot be accessed by XStreamBrowser due to differences in
the Windows operating system that preclude the necessary configuration, WaveStudio includes an
Automation Browser feature that exposes the instrument's COM object hierarchy, the same as does
XStreamBrowser for other oscilloscope models.
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MAUI Oscilloscopes Remote Control and Automation Manual
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Part 2: Automation Programming Reference
Part 2: Automation Programming Reference
This section is a guide to the Automation capabilities of Teledyne LeCroy’s MAUI™ (also known as
XStream) oscilloscopes.
While Teledyne LeCroy has always striven to maximize compatibility, the underlying technologies used by
Automation require the Microsoft Windows® operating system (minimum 32-bit), and this system was
introduced only with our MAUI instruments. Automation is not available on the older oscilloscope families.
These instruments can be controlled remotely using legacy IEEE 488.2 remote control commands.
Automation Overview 2-2
XStreamBrowser 2-4
Viewing/Modifying XStream Objects 2-6
VBS Command 2-10
Approach 1: Control from XStreamBrowser 2-11
Approach 2: Program in VBS 2-13
Approach 3: Program Using ActiveDSO 2-17
Approach 4: Program Using VISA 2-20
Control Variables 2-24
Result Interfaces 2-27
Exposing Result Interfaces 2-30
Synchronization 2-35
Application Interactions 2-37
Early and Late Binding 2-38
Automation Programming Rules 2-39
Automation in MATLAB 2-43
Automation in Python 2-46
Automation in C# 2-49
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MAUI Oscilloscopes Remote Control and Automation Manual
Automation Overview
Automation (formerly referred to as “OLE Automation”) is a Microsoft technology that is primarily used to
enable cross-application macro programming. It is based upon the Component Object Model (COM),
which is similar in nature to CORBA more commonly found in the UNIX world. In addition to supporting the
familiar ASCII-based remote commands that have been used to control all Teledyne LeCroy oscilloscopes
for many years, all Windows-based MAUI instruments fully support control by Automation interfaces.
Using COM, the controlling application can run directly on the instrument without requiring an external
controller. Alternatively, it can run from a remote, networked computer using Microsoft’s distributed COM
standard (DCOM).
It is important to note that Automation itself is not language dependent; it can be performed using any
programming language that supports COM.
General Architecture
An application that “exposes Automation objects” is referred to as an “Automation server.” Automation
objects expose “Automation interfaces” to the controlling “Automation client.” The oscilloscope application
on MAUI oscilloscopes (XStream) is an Automation server that can be controlled locally or remotely by
Automation clients.
Automation objects can take the form of:
l"Invisible" objects created by script, such as a Visual Basic script to change oscilloscope settings
and read back the new measurement results
lVisible objects embedded in an application, such as a button that launches a macro containing an
Automation subroutine
Uses of Automation
Automation has many uses:
lInstrument setup (panel files)
lRemote Control from external Windows applications
lExposing waveform data and measurement results to external Windows applications
lCustom math/measurement processing and user interface customizations (with XDEV)
This section concentrates on using Automation for remote set up, control, and waveform/data transfer,
the functions traditionally performed by GPIB remote control.
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Part 2: Automation Programming Reference
Automation Compared to IEEE 488.2 Remote Control
Automation does not necessarily replace the IEEE 488.2 legacy remote command set, which is also
supported by MAUI instruments (and will continue to be). Rather, it augments it and allows another class
of application to be created that can be executed locally or remotely.
Automation, however, can be considered as the “native language of MAUI instruments. All of the
instrument’s controls and features are available to the Automation client, whereas only some of the
instrument features have been implemented in the 488.2 remote command set.
The following table summarizes the differences between the two approaches to remote control:
IEEE 488.2 Remote Control Automation Remote Control
Physical transport TCP/IP and LXI over Ethernet, GPIB,
LSIB, or USBTMC*
Inter-process using COM, inter-PC using
DCOM (TCP/IP)
Textual parsing of instrument
responses required
Yes, all instrument responses need
parsing to extract useful information
No, each element in the Automation
hierarchy appears as a “variable” to the
Automation client
Compatibility with legacy
programs/instruments
Yes, in most cases remote control
applications written for legacy
instruments will work without
modification
No, Automation is a standard first
introduced with MAUI (XStream)
Ability to control the oscilloscope
application from “inside the box”
Yes, by using the VICP (TCP/IP) protocol
to talk to the “localhost
Yes, natively
Ease of use Not trivial, although easier using a tool
such as ActiveDSO** that hides some of
the complexities
Very easy with scripting languages and
MS Office productivity tools
Format of waveform results Binary or ASCII; both require parsing
before use
Arrays of floating point values
Control from MS Office suite Possible via ActiveDSO utility Yes, natively
* Not all interfaces available on all models. GPIB and LSIB available with hardware option.
** ActiveDSO is an ActiveX based driver for Teledyne LeCroy oscilloscopes
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MAUI Oscilloscopes Remote Control and Automation Manual
XStreamBrowser
The XStreamBrowser utility enables you to view, copy, and modify the COM object hierarchy of a
Windows-based MAUI™ oscilloscope from a remote PC. It is essential for writing Automation programs, as
it always shows all the Automation objects on the instrument at the exact current configuration—including
those objects belonging to software options. It can also be used as a remote control console, enabling you
to directly alter the configuration of Automation control variables.
XStreamBrowser is installed on all MAUI oscilloscopes for local browsing, but it may also be installed on
any PC for remote control. You must first allow a DCOM connection between the PC and oscilloscope,
then connect the XStreamBrowser to the device. The browser window is populated when the connection
is successful.
Note: WaveSurfer 3000 users should install the WaveStudio software instead of
XStreamBrowser. The COM object hierarchy of a connected device is shown in the WaveStudio
Automation Browser.
Caution: The version of XStreamBrowser available for download on our website is a 32-bit version
that will run on 64-bit machines. It is intended only for installation on remote PCs, not on
oscilloscopes. A 64-bit version of XStreamBrowser is already installed on 64-bit MAUI
oscilloscopes. Installing the 32-bit version over this will cause registry conflicts. Likewise, if you
have installed the 64-bit MAUI firmware on your PC, you already have a copy of the 64-bit
XStreamBrowser. If it was uninstalled, reinstall the MAUI firmware, rather than install the 32-bit
version of XStreamBrowser.
Connecting to a Local Device
To launch XStreamBrowser on the oscilloscope:
1. Choose File->Minimize to display the Windows desktop.
2. Double-click the XStream Browser icon.
3. Select the connection icon.
Connecting to a Remote Device
1. Be sure the device is configured to allow a DCOM connection from the PC.
2. Launch the XStreamBrowser.
3. Select the connection icon.
4. Enter the network IP Addressof the device, then click OK.
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Part 2: Automation Programming Reference
Note: Use the IP Address, not the DNS or UNC name. If the oscilloscope application of the device
is not running, initiating the connection from XStreamBrowser will start it; however, it will not
power on a device that is powered off. Be sure the device is turned on before connecting.
When the connection to a device is established, the XStreamBrowser window is populated with the
oscilloscope application object hierarchy.
Root application object hierarchy of XStream, the "engine" of MAUI oscilloscopes.
Refreshing the Display
If you change the state of the oscilloscope in any way while connected to XStreamBrowser, select the
icon to refresh the object hierarchy. While settings you "push" from XStreamBrowser will appear
immediately, settings changed elsewhere must be "pulled" into the XStreamBrowser browser display.
Disconnecting
Only one connection may be made at one time. To disconnect from the device, choose
File > Close Session.
Use the window closebox or choose File > Exit to close the XStreamBrowser application.
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MAUI Oscilloscopes Remote Control and Automation Manual
Viewing/Modifying XStream Objects
The number of different objects in a complete oscilloscope setup is obviously large and changes with the
installation of new firmware and software options. XStreamBrowser helps you quickly find the object path
and valid values corresponding to any instrument control.
The object hierarchy exposed by MAUI instruments is rooted at the Application object. This object is
always named LeCroy.XStreamDSO.
All major instrument subsystems are available from this object, and many of these subsystems
themselves may be brokendown further. As new software options are activated on the oscilloscope,
these subsystems are added to the Application object hierarchy.
Anything exposed by the object hierarchy can be controlled or read back via Automation.
Object Hierarchy
The left-hand pane of the XStreamBrowser window contains an
expandable navigation "tree." The object hierarchy is tiered; for
example, the Acquisition subsystem is comprised of a variety of
objects, each with child objects.
The right-hand pane shows the Control Variables or Properties
related to the object selected from the navigation tree.
Control Variables
The majority of the items you will find as you expand the navigation tree are Control Variables, or CVARs
for short. These are shown as yellow folders in the XStreamBrowser window.
CVARs provide an interface for accessing scope configurations and for executing methods and actions.
When viewed from XStreamBrowser, many CVARs appear to be properties, but are actually objects with
properties such as Name,Value, and Type, to name a few. See Control Variables for a description of CVAR
Types, Properties, and Methods.
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Part 2: Automation Programming Reference
CVAR properties shown in the right-hand pane of XStreamBrowser window.
The Range/Helpstring column provides short form information about the possible values the variable can
take.
The Flags/Status column contains coded information about the object.
Flag/Status Indicates
RFor CVARs: Read only.
For Properties: Readable.
WFor CVARs: Wrapping, incrementing the value will "wrap around" from max. to min., or vice versa.
For Properties: Writable.
H Hidden: not visible on any GUI dialog or menu.
g Grey: appears "greyed out" on GUI indicating it is
disabled or not settable.
B Backwards: incrementing the CVAR value will decrease the value.
N Nonvolatile: value is saved in the application's "nonvolatile" settings file. These CVARs are typically
user preferences and are not affected by Recall Default Setup.
A AutoRepeat: the CVAR action should be repeated if a button on the GUI is held down.
M MultiLine: the CVAR value may be rendered on
multiple lines of the GUI.
L LateUpdate: the CVAR value may be updated when it is read/refreshed.
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MAUI Oscilloscopes Remote Control and Automation Manual
Actions and Methods
Besides the configuration CVARs, automation also provides for Actions that may be applied at the
application or subsystem level.
For example, to clear sweeps for all subsystems, the Automation command would be:
app.ClearSweeps
Methods are similar to Actions but may take parameters from the caller and may possibly return a value,
whereas, Actions do not support any parameters or return values. An example of a Method is
app.Acquisition.Acquire, which takes both "timeout" and "force trigger" arguments.
Result Interfaces
The grey folders are Result Interfaces. Result Interfaces contain more than just the basic results of
oscilloscope operations, such as waveform data and measurement values; they include information about
horizontal and vertical resolution, event times, number of sweeps, histogram peaks, etc. The Type column
of the XStreamBrowser window shows the result interface type. See Result Interfaces for a description of
the Types and Variables.
Collections
Collections, which are shown as pink folders in XStreamBrowser, contain sets of similar objects. For
example, the app.Acquisition.Channels collection contains input channel objects (C1, C2, etc.). Objects in
Collections folders are dynamically linked to those in the yellow folders; changing the value in either place
changes it everywhere. Collection subfolders are referenced by indexing the collection name with the
subfolder name.
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Part 2: Automation Programming Reference
Copying from XStreamBrowser
When a variable is selected from the right-hand pane, the message bar at the bottom of the screen shows
the full object path in correct notation for sending as an Automation command:
Right-click and choose Copy Path. The text is automatically placed in the clipboard, from where it can be
easily copied into remote control programs.
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MAUI Oscilloscopes Remote Control and Automation Manual
VBS Command
For users who wish to harness the power of Automation, but are currently using “traditional” GPIB remote
control commands, there is a solution: the VBS command. This will enable you to control the advanced
features of MAUI oscilloscopes that are not supported by GPIB commands.
VBS is also used to encapsulate Automation commands whenever there is a remote connection to the
oscilloscope other than DCOM (ActiveDSO, VISA driver, etc.).
Below are two, equivalent methods for setting the V/Div of Channel 1. The first examples uses a GPIB
command, VDIV; the second uses the VBS command:
C1:VDIV 0.5
VBS 'app.Acquisition.C1.VerScale = 0.5'
In its query form, the following are equivalent:
C1:VDIV?
VBS? 'return = app.Acquisition.C1.VerScale'
Note: For the query form, including 'return = object' is important, as it indicates which value you
wish to be returned to the caller.
The VBS Command/Query is documented in more detail in the GPIB command reference.
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Approach 1: Control from XStreamBrowser
When a PC has a DCOM connection to a networked oscilloscope, a copy of XStreamBrowser running on
the PC has the same read/write capabilities as the version that is running locally on the oscilloscope. The
oscilloscope's entire XStream object hierarchy is exposed and editable from XStreamBrowser. This is
perhaps the simplest way to remotely control the oscilloscope.
This exercise modifies the oscilloscope channel C1 Vertical Scale setting directly from XStreamBrowser
installed on the PC.
Make the Connection
1. Connect the oscilloscope to your LAN, or directly to the PC using a cross-over cable.
2. Turn on the oscilloscope and go to Utilities > Utilities Setup > Remote and choose control from
TCP/IP.
3. Create a DCOM connection to the oscilloscope.
4. Download and install a copy of XStreamBrowser on the PC.
5. Open XStreamBrowser on the PC and connect to the oscilloscope.
6. When the oscilloscope appears in the Devices list, click on it to show the application hierarchy.
Find and Modify the Object
The Vertical settings associated with channels are part of the Acquisition subsystem, as they control the
characteristics of the ADCs at the input, directly affecting acquisition.
Since we're looking to modify a setting that affects the Acquisition subsystem, expand the Acquisition
folder to display the C1 object. Select the C1 object folder so that the C1 CVARs appear in the right-hand
window pane.
As you scroll down, you'll see the VerScale CVAR, showing whatever value was last set for that channel on
the oscilloscope, in this example, 50.0 mV.
XStreamBrowser tell us the following about this control:
lThe Type column shows it is a DoubleLockstep
lThe Flags/Status column shows B, meaning it is Backwards and incrementing the CVAR will
decrease the value.
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MAUI Oscilloscopes Remote Control and Automation Manual
lThe Range/Helpstring column shows an acceptable range of 0.002 to 1 step 0.0005. meaning it
can be set anywhere from 0.002 to 1 in increments as small as .0005. If Variable Gain is left on, the
next value possible is 0.0025.
lThe additional statement that it is "locked to 1 2 5, fine grain..." is fully visible if we right-click on the
VerScale line and choose Copy to display the Set Control Variable dialog:
While fine grain (Variable Gain) adjustments are allowed on this oscilloscope (true), the Var. Gain
setting is currently off (on=false), so the control would adjust in stepped increments of 1, 2, or 5
units (in sequence) were it being operated from the oscilloscope touch screen. Starting at 0.002,
the next value would be 0.005.
Enter a new Value of 100 mV and choose to Set this value.
Back on the XStreamBrowser window, you will see that the C1 VerScale setting has changed:
And the oscilloscope immediately reflects this change, as well:
Note that here we can see the Var. Gain setting is deselected.
That's all that is required to remotely set up a MAUI oscilloscope from your PC.
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Part 2: Automation Programming Reference
Approach 2: Program in VBS
Setup (or Panel) files, which are used to save and recall the state of the instrument between sessions, are
traditionally binary files with an internal structure that is neither documented nor obvious to the user. In
MAUI oscilloscopes, however, this is not the case. Setups are ASCII text files that contain a complete
Visual Basic Script “program”. In effect, each time a panel is saved, the instrument writes a program that,
when executed, returns the instrument to the saved state.
VBS programs function like Setup files that are written and executed remotely.
Note: Setup files stored by the instrument have file extension “.lss (LeCroy Setup Script). These
files are syntactically identical to Microsoft VBS files, which have a “.vbs extension.
In this exercise, we'll create and execute a simple VBS program on the PC that:
lConnects to a networked oscilloscope
lPerforms an AutoSetup
lChanges the oscilloscope grid mode
lReads back the Grid Mode and Vertical Scale
lDisconnects
Preliminary Setup
1. As with Exercise 1, it is assumed there is a DCOM connection between the PC and an oscilloscope
on the same network, and that XStreamBrowser is installed on the PC.
2. On the oscilloscope, go to Utilities > Utilities Setup > Remote and confirm that the TCP/IP (VICP)
setting is selected. Note the oscilloscope's IP address.
3. Open XStreamBrowser and NotePad or another text editor on the PC.
Program
Note: Characters in angle brackets are placeholders. Omit the brackets from your code.
Connect
CreateObject is the Visual Basic function that creates an instance of a COM Server. The argument
LeCroy.XStreamDSO” refers to the oscilloscope application. Once it has instantiated (connected to) the
oscilloscope application, it requires some kind of ‘handle’ (pointer) so that it can later be used to
communicate with the instrument. CreateObject returns a handle, which is stored in the app variable.
In the text editor, write the VBS connect string:
Set app = CreateObject("LeCroy.XStreamDSO")
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MAUI Oscilloscopes Remote Control and Automation Manual
Note: Only a single instance of the XStream software can run on a system at one time. If the
software is already running when CreateObject is called, a handle to that running instance is
returned. If XStream is not running, it will be started.
AutoSetup
AutoSetup is an Action that utilizes default Vertical and Timebase settings and a 50% level Edge trigger to
quickly set up an acquisition on the oscilloscope. The first active input channel is used as the triggger
source.
AutoSetup occurs "above" the individual subsystems in the XStream application hierarchy, at the root
object LeCroy.XStream.DSO. In XStreamBrowser, you will find it in the root folder. Had this command
involved only C1, for example, you would have navigated to Acquisition > C1 and selected it to show the C1
CVARs.
You can see AutoSetup is an Action from the Type column. Most of what occurs at this top level are
Actions.
Right-click on AutoSetup and choose Copy Path.
Go back to the text editor window, and paste the AutoSetup command into your program:
app.AutoSetup
Change Grid Mode
The Grid Mode determines how many grids appear on the oscilloscope display at once. This is one setting
where a change can be perceived without an input signal. Grid Mode affects the oscilloscope display, so it
is found within the Display subsystem.
In XStreamBrowser, expand the Display folder until you see the CVARs in the right-hand window pane.
Navigate to the object GridMode. You can see the valid settings in Range/Helpstring include Auto, Single,
Dual, Quad, etc.
Right-click on GridMode and choose Copy Path. You'll see from the XStreamBrowser window message
bar that the object path is:
app.Display.GridMode
Note that the controls are arranged in a hierarchy, with each level delimited by a decimal point ( . ).
Paste the line into your remote control program, then set the new value of Quattro:
app.Display.GridMode = “Quattro”
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Using the app handle, this line of code sets the Grid Mode control of the Display system to the value
Quattro”.
Note: WaveSurfer 3000, WaveSurfer 10, and HDO4000 oscilloscopes only support Auto, Single,
and XY Grid Modes. You can choose any of these for the exercise, but note that if you go from
Auto to Single, the change will only be evident by looking at the Display setup dialog.
Read Back Grid Mode and Vertical Scale
Create a variable to read back the value currently set in the equivalent control. In the text editor, write the
line:
myGridMode = app.Display.GridMode
This line of code retrieves the current value of the app.Display.GridMode CVAR and stores it within the
variable myGridMode.
Note: In Visual Basic Script it is not necessary to “Dimension” variables before using them (for
example, using statements like “Dim myVerScale as Double).
To get the value of the C1 Vertical Scale, create a new line for the variable myVerScale.
In XStreamBrowser, navigate to the Acquisition > C1 folder and click on it to show the CVARs. Right click
on VerScale and Copy Path. Paste it behind the "myVerScale" variable:
myVerScale = app.Acquisition.C1.VerScale
For this exercise, the "read back" method will be the standard Visual Basic Message Box dialog. Add two
lines using the MsgBox function to display the values of the two variables you created:
MsgBox myGridMode
MsgBox myVerScale
Disconnect
Add a line of code to end the program and close the connection to the oscilloscope:
Set app = Nothing
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MAUI Oscilloscopes Remote Control and Automation Manual
Execute
You should see the following script in your text editor:
'Connect to the XStream application
Set app = CreateObject("LeCroy.XStreamDSO")
'Perform action AutoSetup and change grid mode setting
app.AutoSetup
app.Display.GridMode = "Quattro"
'Read back grid mode and vertical scale
myGridMode = app.Display.GridMode
myVerScale = app.Acquisition.C1.VerScale
MsgBox myGridMode
MsgBox myVerScale
'Disconnect
Set app = Nothing
Save the file as Exercise2.vbs.
Open Windows Explorer and navigate to Exercise2.vbs. Double-click on the file to execute it.
If these steps were followed correctly, you should observe the oscilloscope perform an AutoSetup and
enter the Quattro-grid display mode. The new grid mode will be evident from the four grids, one in each
quadrant of the display.
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Part 2: Automation Programming Reference
Approach 3: Program Using ActiveDSO
As not all controllers can utilize the Windows DCOM architecture, there is another simplified method for
remote control of the XStream application: ActiveDSO, Teledyne LeCroy's proprietary Active-X control.
ActiveDSO can be used for much more than just remote control programs, but this exercise shows how
the same Automation commands used for remote control in Exercise 2 could be sent using ActiveDSO,
instead.
ActiveDSO also has the advantage of working with programming languages besides Visual Basic, such as
Python and Visual C++, making it easy to utilize as a remote control/waveform transfer subroutine within
other programs, or as part of a custom remote control interface. For more information, see the ActiveDSO
topic in the "Making the Remote Connection" section.
Preliminary Setup
1. Download ActiveDSO from teledynelecroy.com (see Resources) and install it on the PC.
2. Open XStreamBrowser and NotePad or another text editor on the PC.
3. Turn on the oscilloscope. For this exercise, we'll continue to use VBS and a LAN connection, so
confirm the oscilloscope is connected to LAN (or has a cross-over connection to your PC).
4. Go to Utilities > Utilities Setup > Remote and confirm the TCP/IP (VICP) setting.
5. Note the oscilloscope's IP address.
Program
Note: Characters in angle brackets are placeholders. Omit the brackets from your code.
Connect
In the text editor, instantiate the ActiveDSO control:
Set dso = CreateObject("LeCroy.ActiveDSOCtrl.1")
Then, invoke the MakeConnect method, in this case using the oscilloscope's IP address:
Call dso.MakeConnection("IP:<IP address>")
This method could have used USBTMC, GPIB, or any other supported connection type. You would want to
be sure to choose control from that same interface on the oscilloscope Remote dialog.
AutoSetup
Besides the instantiation method, the most obvious difference between using native VBS and using
ActiveDSO is in how commands are sent. With ActiveDSO, Automation controls are nested within the VBS
command. Write the line:
Call dso.WriteString("VBS 'app.AutoSetup'", 1)
The Boolean "1" is telling the XStream application to interpret the command immediately.
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MAUI Oscilloscopes Remote Control and Automation Manual
You could also use WriteString with the legacy IEEE 488.2 command set. For example, write:
Call dso.WriteString("C1:VDIV 200 mV", 1)
This command will reset the Vertical Scale, same as did the "app.C1.VerScale" Automation command sent
in Exercise 1. Either legacy commands or VBS Automation commands can be sent using WriteString.
Change Grid Mode
Add another line to the program to change the Grid Mode from Quattro back to Auto, or any other grid
mode supported by your oscilloscope model:
Call dso.WriteString("VBS 'app.Display.GridMode = "Auto"'", 1)
If you wish, add lines for any other setup changes you'd like to make, using the XStreamBrowser to find the
CVAR and copying the path into the VBS command.
Read Back Grid Mode and Vertical Scale
There are several ActiveDSO methods to read back parameter results and waveform data, but a simple
way to read setup values is to use the VBS? query with the Automation control.
In your program, write:
Call dso.WriteString("VBS? 'app.Display.GridMode'", 1)
Call.dso.WriteString("VBS? 'app.Acquisition.C1.VerScale'", 1)
Notice we're still using WriteString to "read back," as what we're doing is writing the string that is the VBS
query. The query, by its nature, returns information. Again, we're including the Boolean 1 that tells the
oscilloscope to interpret the instruction immediately.
What we still need to specify is how to display the result text:
Call dso.WriteString("VBS? 'return = app.Acquisition.C1.VerScale'", 1)
myString = ReadString(numbytes)
MsgBox (myString)
Disconnect
Write the following lines to disconnect from the XStream application and end the program:
dso.Disconnect
Set dso = Nothing
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Execute
You should now see the following program, or similar, in your text editor:
'Connect to the XStream application
Dim dso As Object
Set dso = CreateObject("LeCroy.ActiveDSOCtrl.1")
Call dso.MakeConnection("IP:<IP address>")
'Send commands to AutoSetup, change grid mode and vertical scale
Call dso.WriteString("VBS 'app.AutoSetup'", 1)
Call dso.WriteString("C1:VDIV 200 mV", 1)
Call dso.WriteString("VBS 'app.Display.GridMode = "Auto"'", 1)
'Query grid mode and vertical scale, show result in Message Box
Call dso.WriteString("VBS? 'app.Display.GridMode'", 1)
Call.dso.WriteString("VBS? 'app.Acquisition.C1.VerScale'", 1)
Call dso.WriteString("VBS? 'return = app.Acquisition.C1.VerScale'", 1)
myString = ReadString(numbytes)
MsgBox (myString)
'Disconnect
dso.Disconnect
Set dso = Nothing
Save the file as Exercise3.vbs.
Open Windows Explorer and navigate to Exercise3.vbs. Double-click on the file to execute it.
If these steps were followed correctly, you should again observe the oscilloscope perform an AutoSetup
then change display mode and vertical scale. Check the C1 descriptor box to see that the Vertical Scale
has changed.
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MAUI Oscilloscopes Remote Control and Automation Manual
Approach 4: Program Using VISA
If you do not wish to utilize ActiveX controls like ActiveDSO, any programming language that can connect
through VISA can be used to send Automation commands. Teledyne LeCroy oscilloscopes are designed to
work with VISA drivers for ENET, USBTMC, or GPIB remote connections. It is not necessary to have a
DCOM connection when you are using a VISA driver.
In this exercise, we'll create a Python script designed to connect over the LAN, as in the previous exercise,
but using LXI remote control settings.
Note: All the code examples given here use the LXI VISA resource string, not the TCP/IP VISA
resource string. Both the TCP/IP and LXI settings utilize the TCP/IP layer, but the higher-level
protocol is different, as is the VISA resource string. You can use the LXI option to communicate
with the oscilloscopes even if your network is not set up to be LXI compliant.
Preliminary Setup
This exercise requires a bit more setup than the previous, but by doing so, it will better demonstrate how
you may use Automation to set up and retrieve measurement data.
1. On the PC, install a VISA driver , Python, and the compatible Python for Windows extensions.
2. Turn on the oscilloscope. Be sure it is connected to your LAN (do not use a cross-over cable for this
exercise).
3. Connect one of the passive probes delivered with your oscilloscope to the Cal Out/Aux Out on the
front of the instrument (what it is named will vary by model) and the C1 input.
4. Go to Utilities > Utilities Setup > Aux Output and choose to output a 1 KHz, 1 Volt Square Wave
or whatever is the default selection for your oscilloscope (there should be a button).
5. Adjust your timebase until you see a stable pulse on the oscilloscope.
6. Go to Utilities > Utilities Setup > Remote and select the LXI (VXI-11) setting. Note the
oscilloscope's IP address.
7. On the PC, open XStreamBrowser and Notepad or another text editor.
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Program
Note: Characters in angle brackets are placeholders. Omit the brackets from your code.
Connect to the Oscilloscope
In your text editor, write these lines to make the remote connection to VISA and to the oscilloscope:
import visa
rm = visa.ResourceManager()
lecroy = rm.open_resource("TCPIP0::<hostname|IP address>::INSTR")
lecroy.timeout = 5000
lecroy.clear()
If your oscilloscope and PC are both known to the same network name server, you can use the hostname
syntax (e.g., "TCPIP0::LCRY0450N70355::INSTR") instead of the actual IP address.
The timeout of 5000 milliseconds ensures the oscilloscope will wait 5000 milliseconds for operations to
complete whenever writing commands or reading responses. Reading continues until the entire response
is received (EOI is reached) or for 5 full seconds. After 5 seconds, there will be a "time out" error.
The clear is intended to clear out the buffers on the oscilloscope listing the commands sent to it and also
responses sent from it. Clear removes anything leftover from a previous use and is a good practice as a
first step in any program.
Several other preliminary settings can be made to prepare the general oscilloscope "environment" prior to
writing new setups or reading measurements. In your program, type:
lecroy.write("COMM_HEADER OFF")
lecroy.write(r"""vbs 'app.settodefaultsetup' """)
The command "COMM_HEADER OFF" is a legacy 488.2 command that tells the oscilloscope "don't return
the command header with query result." This helps to read back values in a format that is more friendly to
being viewed on screen or imported into other programs.
Recalling the default setup, while not required, ensures that all setups are at a known baseline value before
you begin.
Notice that the method 'app.settodefaultsetup' is the first actual Automation command being passed to
the oscilloscope. It is enclosed in the VBS command wrapper, as are all Automation commands sent by
remote connection, rather than through a COM/DCOM connection.
Note: The triple quotes around the VBS command are required because quotes around the values
within the command could be interpreted by Python as the end of the command string. You would
probably create a function to put the VBS wrapper around whatever automation commands you
wanted to send. Here, we're showing each full line of code for demonstration.
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MAUI Oscilloscopes Remote Control and Automation Manual
Timing and Synchronization
In any remote control program, it is important to set up "checks," periodically querying that processes are
complete before starting new ones, or that old measurements are cleared before taking new ones, etc.
Querying the 'app.WaitUntilIdle' method can tell your program when it is safe to proceed.
In your program, enter the query:
r = lecroy.query(r"""vbs? 'return=app.WaitUntilIdle(5)' """)
This will inform the program when the Recall Default setup has been completed and the oscilloscope
application is idle for 5 milliseconds (the default unit for this command) before going on to set up the new
acquisition.
Set Up Acquisition
Every program that is to acquire new data, whether raw waveform data or post-processing measurement
results, must set up an acquisition. It is important before taking any new acquisition to stop the previous
one. Failure to do this is a principal reason for inaccurate measurements. Add the line:
lecroy.write(r"""vbs 'app.acquisition.triggermode = "stopped" ' """)
Using XStreamBrowser, find suitable replacements for <value> in following acquisition CVARs, and add
these lines to your program:
lecroy.write(r"""vbs 'app.acquisition.trigger.edge.level = <value>' """)
lecroy.write(r"""vbs 'app.acquisition.triggermode = "single" ' """)
lecroy.write(r"""vbs 'app.acquisition.horizontal.maximize = "<value>" ' """)
Be sure not to forget the double quotes around those values that are String or Enum types.
Set Up Measurements
As with the default setup, it is a good idea to clear all measurement definitions and previous sweeps before
proceeding with new measurements:
lecroy.write(r"""vbs 'app.measure.clearall ' """)
lecroy.write(r"""vbs 'app.measure.clearsweeps ' """)
As you may have noticed by now, Automation commands are more granular than legacy 488.2
commands. Generally, more lines of code must be sent to achieve the same end result, because every
relevant application object must be set to a particular state. However, this granularity is also what makes
Automation more powerful.
To set up measurements, we have to first turn on measurements, then turn on statistics, then turn on the
parameter, then set what we want the parameter to measure, then set the parameter source (what input
it will measure), etc. Using XStreamBrowser, find a suitable <value> for 'app.measure.p1.paramengine'.
Tip: Select a single source measurement appropriate to your 1 KHz, 1 V pulse wave.
lecroy.write(r"""vbs 'app.measure.showmeasure = true ' """)
lecroy.write(r"""vbs 'app.measure.statson = true ' """)
lecroy.write(r"""vbs 'app.measure.p1.view = true ' """)
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lecroy.write(r"""vbs 'app.measure.p1.paramengine = "<value>" ' """)
lecroy.write(r"""vbs 'app.measure.p1.source1 = "C1" ' """)
Acquire
Now write code to arm the acquisition. Again, timing is important: this example takes 10 acquisitions,
forcing a trigger if none occurs after 0.1 seconds (the second and first arguments, respectively, of
'app.acquisition.acquire'), then uses the 'app.WaitUnitIdle' method to wait for 5 seconds after all
acquisition processing is complete before measuring.
for i in range(0,10):
r = lecroy.query(r"""vbs? 'return=app.acquisition.acquire( 0.1 , True )' """)
r = lecroy.query(r"""vbs? 'return=app.WaitUntilIdle(5)' """)
if r==0:
print "Time out from WaitUntilIdle, return = {0}".format(r)
Read Back Measurement Results
Read the Out.Result object of the P1 parameter into a variable of your choosing, and print the value.
Just as the Automation commands were sent within the VBS command wrapper, the Automation query is
sent within the VBS? query wrapper. For <var>, you can substitute the name of the measurement you
choose earlier.
<var> = lecroy.query(r"""vbs? 'return=app.measure.p1.out.result.value' """)
print "<var> = {0}".format(<var>)
Disconnect
Finally, close the remote connections to the scope and to VISA, in the reverse of the order in which you
opened them:
lecroy.close()
rm.close()
Execute
Save the file as Exercise4.py. Navigate to the file on your PC and execute it.
If these steps were followed correctly, you should observe the oscilloscope resume the Default Setup. The
Measure table should appear below the waveform, showing the results of the measurement you set in P1.
Meanwhile, the following should appear in your console:
Time out from WaitUntilIdle = <value>
<var>=<value>
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Control Variables
Traditionally, properties presented to an Automation client are simple “variables” with types such as
Integer (int), String (BSTR), Floating Point (single, double), etc. However, on MAUI oscilloscopes, CVARs
are an extension of the traditional Automation pattern, without affecting how they appear to most
Automation clients (see the topic on early/late binding). This enables an Automation client to not only set
and query the current value of a control, but also to query its limits. This is useful in the generation of
instrument-independent applications, or applications that present scope controls in a graphical user
interface in which limits are required.
Take a CVAR such as VerScale (Volts/Div). This may be set and queried in Visual Basic as follows:
app.Acquisition.C1.VerScale = 0.5
CurrentValue = app.Acquisition.C1.VerScale
The following are also supported:
minValue = app.Acquisition.C1.VerScale.GetMinValue
maxValue = app.Acquisition.C1.VerScale.GetMaxValue
Control Variable Types
Control variable type designations are defined as follows:
Type Definition
Action Action (no arguments or value)
Bool Boolean value given as { false| true} or { 0| -1 }
Color RGB value triplex "R,G,B"
Double Double-precision floating point value
DoubleLockstep Double-precision floating point value locked to a non- linear (e.g., 1, 2, 5) stepped sequence.
Enum List value (e.g., “Orange,” “Apple,” “Pear”)
FileName Legal DOS path
Integer 32-bit Integer value
String String value
The Type column of the XStreamBrowser window shows the control type.
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Properties and Methods
The properties and methods available for each control are type-specific. Listed below are the most
commonly used:
Type Properties and Methods
Integer VARIANT Value
Value(VARIANT)
int GetAdaptedValue
SetRequestedValue(int)
int GetRequestedValue
int GetDefaultValue
int GetGrain
int GetMax
int GetMin
Increment(int)
Double VARIANT Value
Value(VARIANT)
double GetAdaptedValue
SetRequestedValue(double)
double GetRequestedValue
double GetDefaultValue
double GetGrainValue
double GetMaxValue
double GetMinValue
Increment(int)
DoubleLockstep See Double
Enum VARIANT Value
Value(VARIANT)
int GetAdaptedValue
SetRequestedValue(int)
int GetRequestedValue
int GetDefaultValue
int GetMax int GetMin
int GetNumberOfValueStates
Increment(int)
BSTR GetRangeStringScreen
BSTR GetRangeStringRemote
String VARIANT Value
Value(VARIANT)
int GetMaxLength
BSTR GetRequestedValue
BSTR GetAdaptedValue
SetRequestedValue(BSTR)
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MAUI Oscilloscopes Remote Control and Automation Manual
Type Properties and Methods
Bool VARIANT Value
Value(VARIANT)
BOOL GetAdaptedValue
BOOL GetRequestedValue
BOOL GetDefaultValue
Set
Clear
Action ActNow
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Result Interfaces
"Out.Result" properties are results of the last completed acquisition. They are not affected if other controls
are changed after that acquisition was completed. This distinction between "Out.Result" properties and
other controls is most important when the trigger mode is Single or Stopped. You should treat "Out.Result"
properties as read-only.
Tip: In almost all remote control applications, it is highly recommended that you STOP acquisitions
before accessing result data. Most remote control problems are caused by failure to follow this
practice.
Several of the Out.Result properties mention the "frame": this is the term used to describe the visible
portion of the trace, which is generally smaller than the acquired waveform. The frame could be used, for
example, to display a 500 point window onto a 1Mpt. trace, or to show the Vertical center 10 mV of a 100
mV peak trace.
Several properties, most significantly the DataArray object, are variants containing either a one or two
dimensional array. Dimension the target variable as a variant type, and assign the DataArray property to it.
See DataArray for examples of its use within each of the Result interfaces.
Result Interface Types
Result Interface type designations are as follows:
TYPE DEFINITION
Digital Digital (bi-state) waveform generated by mixed-signal oscilloscope.
Histogram Histogram trace.
Param Individual results and result arrays for measurement parameters and Pass/Fail test qualifiers.
Persist Eye diagrams or other waveshapes that are the result of overlaying multiple waveforms.
Table Tabular results primarily used in conjunction with the various low-speed serial decoding options.
Waveform Basic Voltage vs. Time waveforms.
XY XY waveforms.
Digital
The Digital interface is found when using one of the mixed-signal oscilloscope options to generate digital
(bi-state) waveforms. These waveforms are contained in the Digitalxtrace name, where x= 1, 2, 3 etc.
Each Digitalxtrace is a bus that may contain multiple digital lines, with a maximum number dependent on
the capabilities of the mixed-signal oscilloscope option. The key property in the Digital interface is the
DataArray, which is a 2D array containing the value of each sample of each digital line in the bus.
Example paths to Digital Result interfaces:
app.LogicAnalyzer.Digital1.Out.Result
app.LogicAnalyzer.Digital2.Out.Result
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Histogram
The Histogram interface is used for all histogram traces. Histograms can be configured on most
oscilloscopes as a math function (Fx). Histograms are also used in various analysis modes, especially on
Serial Data Analyzers, where the HTIE trace is the source data for the algorithm to calculate Total jitter
(Tj). The key property is BinPopulations, which is a 1D array of the bin populations.
Example paths to HTIE Result interfaces:
app.Math.F1.Out.Result
app.SDA.Htie.Out.Result
Note: This example assumes that F1 is set up as a Histogram.
Param
The Parameter interface is used in the Measurement and Pass/Fail systems to hold both individual results
and result arrays. The key properties for the Parameter interface are Value and ValueArray. Value holds
the last measurement or P/F result, while ValueArray holds all measurements taken for the last
acquisition.
Example paths to Param Result interfaces:
app.Measure.P1.Out.Result
app.Measure.P1.Sdev.Result
app.Measure.Measure("P1").Out.Result
Persist
The Persist interface is most often found when using software options that create eye diagrams or other
waveshapes that are the result of overlaying multiple waveforms. (Note that this does not apply to the
Persistence display mode.) The key property in the Persist interface is the DataArray, which is a 2D array
containing the population of each pixel of the persistance map.
Example paths to Persist Result interfaces:
app.SDA.Eye.Out.Result
app.SDA.Eye2.Out.Result
Table
Table results interfaces are used primarily used in conjunction with the various low-speed serial decoding
options, such as CAN, I2C, SPI, UART, etc. When the table is displayed, the user has access to information
about the messages decoded for the last acquisition. Retrieving data from the Table interface involves
some knowledge of the tables structure, in terms of the columns that are displayed and the cell types.
The CellType and CallValue are the key properties to use to retrieve the tables data. See the information in
the CellValue property for more information.
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Example paths to Table Result interfaces:
app.SerialDecode.Decode1.Out.Result.
app.SerialDecode.Objects("Decode2").Out.Result
Waveform
Waveform Results interfaces can be found wherever there are basic Voltage vs. Time waveforms.
Examples include channel (Cx), memory (Mx), math function (Fx) and zoom (Zx) traces, as well as others
that are associated with specific analysis packages, such as the Power waveform used in the PMA2
package. In general, these waveforms are usual voltage vs time, unless a current probe or other method of
changing the vertical units (e.g. the Rescale Math function) is employed. The key property in the
Waveform interface is the DataArray, which is a 1D array containing the value of each sample in the
waveform.
Example paths to Waveform Result interfaces:
app.Acquisition.C1.Out.Result
app.Acquisition.Channels("C1").Out.Result
app.Math.F2.Out.Result
app.Zoom.Z3.Out.Result
app.SDA.Btub.Out.Result
Note: Traces like F2 and Z3 can hold waveforms like histograms, which do not use the Waveform
interface.
XY
The XY interface is used on XY waveforms. Users can create an XY waveform by selecting this option in
the Display Setup screen. XY waveforms allow you to see how the signal on one channel moves in
relation to another. The key property is the DataArray, which is a 2D array that returns the voltages on the
X and Y sources for each XY pair.
Example path to the XY Result interface:
app.Math.XY.Out.Result
Result Variable Types
TYPE DEFINITION
Integer 16-bit signed integer
Long 32-bit signed integer
Double 8-byte floating point type
String Array of characters
Object Object with its own interface
Variant Variable that is dimensioned without indicating a variable type
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MAUI Oscilloscopes Remote Control and Automation Manual
Exposing Result Interfaces
Waveform Data
Waveform data is exposed as a simple array, no deciphering of proprietary binary formats is performed, as
was necessary in the past.
This example is coded as an Excel macro in VBA that would be assigned to a button. The macro reads the
number of samples in the waveform and places it in cell B1 of the Excel spreadsheet. It then reads all
available sample data values and copies them into cells in the first column (A) of the spreadsheet
(A1...Axx). The green comment text explains what each section of the script accomplishes.
Sub Button1_Click()
' Connect to the oscilloscope
Set app = CreateObject("LeCroy.XStreamDSO")
' Query the number of samples in C1 and store in cell "B1"
numSamples = app.Acquisition.C1.Out.Result.Samples
Cells(1, 2)
Value = numSamples
' Access waveform data array, fill first column of the spreadsheet
wave = app.Acquisition.C1.Out.Result.DataArray
For i=0To numSamples - 1
Cells(i + 1, 1).Value = wave(i)
Next i
End Sub
Note: When moving result data into Excel, ensure that the record length is < 64 k samples, since
Excel has a limit on the number of rows in a spreadsheet. Ideally, you should start experimenting
with short (500 point) records.
Result Status
The waveform result object described above includes a status property (bit-field) that reflects the current
status of the trace. This includes both warning and ‘error’ conditions, as described below.
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Description Value Bit #
LEC_Valid 0x0 N/A
LEC_Invalid 0x0000000000001 0
LEC_Overflow 0x0000000000002 1
LEC_Underflow 0x0000000000004 2
LEC_ContainsUndefinedValues 0x0000000000008 3
LEC_LessThan 0x0000000000010 4
LEC_GreaterThan 0x0000000000020 5
LEC_NotAPulse 0x0000000000040 6
LEC_NotCyclic 0x0000000000080 7
LEC_Averaged 0x0000000000100 8
LEC_UnlockedPLL 0x0000000000200 9
LEC_OtherError 0x0000000000400 10
LEC_OtherWarning 0x0000000000800 11
LEC_OtherInfo 0x0000000001000 12
LEC_InputsIncompatible 0x0000100000000 32
LEC_AlgorithmLimitsReached 0x0000200000000 33
LEC_BadDefinition 0x0000400000000 34
LEC_TooFewData 0x0000800000000 35
LEC_TooManyData 0x0001000000000 36
LEC_UniformHorizIntervalRequired 0x0002000000000 37
LEC_BadUnits 0x0004000000000 38
LEC_DataRangeTooLow 0x0008000000000 39
LEC_DataUndersampled 0x0010000000000 40
LEC_PoorStatistics 0x0020000000000 41
LEC_SlowTransitionTime 0x0040000000000 42
LEC_DataResampled 0x0080000000000 43
LEC_DataInterpolated 0x0100000000000 44
LEC_MeasurementScaleImprecise 0x0200000000000 45
LEC_NoDataAvailable 0x0400000000000 46
LEC_SomeCummulatedResultsInvalid 0x0800000000000 47
LEC_InsufficientMemory 0x1000000000000 48
LEC_ChannelNotActive 0x2000000000000 49
LEC_UseStatusDescription 0x4000000000000 50
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MAUI Oscilloscopes Remote Control and Automation Manual
Measurements
Measurement results are read in the same way as Waveforms. The following VBA example, when copied
into an Excel macro, enables the Standard Vertical parameters, then transfers the eight measurement
values into the spreadsheet (at cells C1 to C8).
' Create Button in Excel
Sub Button1_Click()
' Connect to the oscilloscop
Set app = CreateObject("LeCroy.XStreamDSO")
' Enable Standard Vertical Parameters
app.Measure.MeasureMode = "StdVertical"
' Transfer the 8 parameter values into the spreadsheet
Cells(1, 3).Value = app.Measure.P1.Out.Result.Value
Cells(2, 3).Value = app.Measure.P2.Out.Result.Value
Cells(3, 3).Value = app.Measure.P3.Out.Result.Value
Cells(4, 3).Value = app.Measure.P4.Out.Result.Value
Cells(5, 3).Value = app.Measure.P5.Out.Result.Value
Cells(6, 3).Value = app.Measure.P6.Out.Result.Value
Cells(7, 3).Value = app.Measure.P7.Out.Result.Value
Cells(8, 3).Value = app.Measure.P8.Out.Result.Value
' Clean up
Set app = Nothing
End Sub
Statistics
Statistics are also available for each parameter using two different calls:
result = app.Measure.P1.mean.Result.Value
result = app.Measure.P1.max.Result.Value
result = app.Measure.P1.min.Result.Value
result = app.Measure.P1.num.Result.Value
result = app.Measure.P1.sdev.Result.Value
result = app.Measure.P1.Statistics("mean").
Result.Value result = app.Measure.P1.Statistics("max").
Result.Value result = app.Measure.P1.Statistics("min").
Result.Value result = app.Measure.P1.Statistics("num").
Result.Value result = app.Measure.P1.Statistics("sdev").
Result.Value
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In addition, the data used to display the Histicon is available using the “histo” statistic:
Sub Button1_Click()
Set app = CreateObject("LeCroy.XStreamDSO")
bins = app.Measure.P5.Statistics("histo").Result.BinPopulations
numBins = app.Measure.P5.Statistics("histo").Result.bins
For i=0To numBins - 1
Cells(i + 1, 4).Value = bins(i)
Next I
Set App = Nothing
End Sub
Programming Examples
Populate Spreadsheet with Waveform Result Data
This VBA macro attached to a button (in an application that supports VBA) performs an FFT of C1 then
populates an Excel spreadsheet with the resulting waveform data.
Sub Button1_Click()
' Connect to the oscilloscope
Set app = CreateObject("LeCroy.XStreamDSO")
' Restore the instrument to its default state
app.SetToDefaultSetup
' Stop acquisitions during setup
app.Acquisition.TriggerMode = "Stopped"
' Turn C2 off (default state leaves C1 and C2 On)
app.Acquisition.C2.View = False
' Configure F1=FFT(C1) using a Blackman-Harris filter
app.Math.F1.View = True
app.Math.F1.Source1 = "C1"
app.Math.F1.Operator1 = "FFT"
app.Math.F1.Operator1Setup.Window = "BlackmanHarris"
' Take a single acquisition, force after 2 seconds if no trigger
app.Acquisition.Acquire 2, True
' Read the FFT, query numSamples in F1 and store in cell "B1"
numSamples = app.Math.F1.Out.Result.Samples
Cells(1, 2).Value = numSamples
' Access waveform data array and fill first column of the sheet
wave = app.Math.F1.Out.Result.DataArray
For i=0To numSamples - 1
Cells(i + 1, 1).Value = wave(i)
Next
End Sub
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MAUI Oscilloscopes Remote Control and Automation Manual
Store Waveform Result Data in a Text File
The VBScript example is very similar to the VBA macro example above, the most notable difference being
the use of a standard system ActiveX control, Scripting.FileSystemObject, to enable the creation of files
containing waveform data in ASCII format. Comment text explains what each section of the script
accomplishes.
' Connect to the oscilloscope
Set app = CreateObject("LeCroy.XStreamDSO")
' Restore the instrument to its default state
app.SetToDefaultSetup
' Stop acquisitions during setup
app.Acquisition.TriggerMode = "Stopped"
' Turn C2 off (default state leaves C1 and C2 on)
app.Acquisition.C2.View = False
' Configure F1=FFT(C1) using a Blackman-Harris filter
app.Math.F1.View = True
app.Math.F1.Source1 = "C1"
app.Math.F1.Operator1 = "FFT"
app.Math.F1.Operator1Setup.Window = "BlackmanHarris"
' Take a single acquisition, force after 2 seconds if no trigger
app.Acquisition.Acquire 2, True
' Readout the FFT
numSamples = app.Math.F1.Out.Result.Samples
' Write the FFT power spectrum into the file, sample by sample
Set fso = CreateObject("Scripting.FileSystemObject")
Set MyFile= fso.CreateTextFile("c:\XStreamFFT.txt", True)
wave = app.Math.F1.Out.Result.DataArray
For i=0To numSamples - 1
MyFile.WriteLine(wave(i))
Next
' Clean up
MyFile.Close
Set fso = Nothing
Set app = Nothing
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Part 2: Automation Programming Reference
Synchronization
Synchronization—or, more specifically, knowing when to read results—is critical when operating a digital
oscilloscope remotely (it is just as important for Automation as for GPIB remote control ). This is especially
true when working with an oscilloscope that uses a multithreaded architecture.
A classic problem seen in the majority of custom applications that control Teledyne LeCroy oscilloscopes
is that the scope is left to free-run in Auto-trigger mode, while simultaneously (and asynchronously) results
are queried.
Several techniques can be used to guarantee the synchronization and consistency of results, whether
they be waveform or parameter measurements, when using the Automation interface.
Timeouts
The following Excel macro example demonstrates the use of a timeout, a useful technique for ensuring
synchronization.
Sub Button1_Click()
' Connect to the oscilloscope
Set app = CreateObject("LeCroy.XStreamDSO")
' Enable Standard Vertical parameters
app.Measure.MeasureMode = "StdVertical"
' Stop the free-running trigger and take a single acquisition
' Use a 10 second timeout in case the acquisition is not complete
app.Acquisition.TriggerMode = "Stopped"
app.Acquisition.Acquire (10, True)
' Read the first parameter value and transfer into the spreadsheet
Cells(1, 3).Value = app.Measure.P1.Out.Result.Value
End Sub
Synchronizing Triggers
The Acquire method arms the acquisition system and waits for a user-specified time for a trigger. The
second argument, a Boolean, specifies whether or not to force a trigger before returning if a trigger
doesnt arrive within the allotted time period. The method also returns a Boolean value signifying whether
or not a trigger arrived. See the reference section for more information on this useful method.
Note: The Acquire method is equivalent to setting the Trigger Mode to “Single”, then executing
WaitUntilIdle.
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MAUI Oscilloscopes Remote Control and Automation Manual
Synchronizing Setups
Another scenario where synchronization is necessary is between changing settings and reading results,
even when no acquisition took place. For this the WaitUntilIdle method is used. This method is “blocking”
and will not return control until the setup request has completed.
An example of WaitUntilIdle usage follows.
Note: WaitUntilIdle is not for use when in Normal or Auto trigger mode.
Sub Button1_Click()
' Connect to the oscilloscope
Set app = CreateObject("LeCroy.XStreamDSO")
' Enable Standard Vertical parameters
app.Measure.MeasureMode = "StdVertical"
' Wait for the change to take place for a max. of 5 seconds
app.WaitUntilIdle(5)
' Read the value of P1 (pkpk) and transfer into the spreadsheet
Cells(1, 2).Value = app.Measure.P1.Out.Result.Value
' Enable Standard Horizontal parameters
app.Measure.MeasureMode = "StdHorizontal"
' Wait for the change to take place for a max. of 5 seconds
app.WaitUntilIdle(5)
' Read the value of P1 and transfer into the spreadsheet
Cells(1, 3).Value = app.Measure.P1.Out.Result.Value
End Sub
Best Practices for Synchronization
lIn almost all Automation applications, it is highly recommended that you stop acquisitions before
accessing result data. Most synchronization problems are caused by failure to follow this practice.
lUse the app.SetToDefaultSetup action to restore the instrument to its default state before setting
the controls required by an application. This eliminates any dependency on the previous
configuration of the instrument. Teledyne LeCroy strives to ensure that the default state of the
instrument is constant from one software release to the next.
lWhen using a result object, verify that the status is valid to ensure that the acquisition and/or
processing was valid.
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Application Interactions
It is not possible to run two simultaneous instances of the oscilloscope application. More than one
simultaneous connection to the instrument via Automation will be accepted, but simultaneous
connections are not recommended. When the final client has been disconnected from the instrument
(server), the oscilloscope application will remain running and will accept further client connections.
Operations that cause Modal Dialogs to appear in the instrument’s display will, by default, disrupt access
from Automation. This behavior can be changed using the app.SystemControl.ModalDialogTimeout and
app.SystemControl.EnableMessageBox controls.
The instrument application can be minimized in order to allow the controlling application to take over the
display and touch panel by means of the app.Minimize control. It can also be resized and repositioned on
the display by means of the app.Top, app.Left, app.Bottom, and app.Right controls.
When an application is running locally on the instrument and requests a connection to the oscilloscope via
Automation, one of two things will happen:
lIf the oscilloscope application is already running, the object returned will be a “pointer” to the
running application.
lIf the oscilloscope application is not running, it will be started.
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MAUI Oscilloscopes Remote Control and Automation Manual
Early and Late Binding
The COM standard on which Automation is built supports two kinds of binding” between client and server:
early (static), and late (dynamic, dispatch). Static binding usually involves a type library and is used
primarily by compiled languages such as C++. In this case, function entry points are resolved at compile
time. Dynamic binding (also known as late binding) involves resolving method and property calls at run
time, as opposed to compile time.
The Automation interfaces in XStream based DSOs use primarily the latter: Dynamic binding. From many
programming languages (VB, VBScript, etc.) this is transparent. But when you are developing applications
in C++, which does not provide late-binding natively, the use of a “helper” class is required. This is
demonstrated below:
#include "stdafx.h"
#include "AtlBase.h" CComModule _Module;
#include "AtlCom.h"
CComPtr<IDispatch> spDso;
// dispatch ptr. to root of object model (app)
CComDispatchDriver ddDso;
int main(int argc, char* argv[])
{
printf("Hello XStream World!\n");
::CoInitialize(NULL);
HRESULT hr = spDso.CoCreateInstance(L"LeCroy.XStreamDSO");
if(SUCCEEDED(hr))
{
ddDso = spDso;
// perform an Auto-Setup (app.Autosetup)
hr = ddDso.Invoke0(L"AutoSetup");
// retrieve a Dispatch ptr. to the app.Display object
CComVariant displayPtr;
hr = ddDso.GetPropertyByName(L"Display", &displayPtr);
CComDispatchDriver ddDisplay(displayPtr.pdispVal);
// enter Dual-grid mode(app.Display.GridMode = "Dual")
hr = ddDisplay.PutPropertyByName(L"GridMode", &CComVariant("Dual"));
}
return 0;
}
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Automation Programming Rules
Follow these rules when writing Automation programs for remote control. See Control Variables and
Result Interfaces for more information about the types and supported methods.
Variables are indicated by italicized text in the examples below.
Values
Enum, String, and Color type values must have double quotes around them, for example:
app.Display.GridMode = "Quad"
Integer, Double, DoubleLockstep, and Bool values do not require quotes:
app.Display.Persisted = false
app.Acquisition.Horizontal.NumSegments = 10
Where objects take multiple arguments, values are given in comma-delimited lists:
app.Acquisition.Acquire(5,true)
app.Acquisition.C1.LabelsText = "Hello,World"
The first Acquisition object above is a Method with both Integer and Bool type arguments; the second is a
CVAR with a multi-value String argument.
To see the correct format and syntax, query the object's current setting. This command can be sent very
easily using the WaveStudio Terminal with a remote connection to the oscilloscope:
VBS? 'return = object'
Units
Generally, units are optional when giving Automation commands. Units are already determined by the
input trace and type of any math functions applied to the trace.
An exception is the Rescale math function command, which creates a second trace that explicitly
changes the vertical units in which the source trace is calculated. Use the following CVARs to reset units:
app.Math.Fx.Equation = rescale(trace)
app.Math.Fx.Operator1Setup.Unit = "menemonic"
See the list of acceptable unit mnemonics in Units and Multipliers
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MAUI Oscilloscopes Remote Control and Automation Manual
Special Cases
Equations
CVARs app.Math.Fx.Equation,app.Math.Fx.EquationRemote, and
app.Measure.Px.Equation are text Strings containing the summary of the math or measure operation.
They can be used to query the current settings, but not to set the function or parameter.
To set up a Math function, use the CVARs app.Math.Fx.Sourcexand app.Math.Fx.Operatorx, and any
objects in the app.Math.F1.OperatorxSetup folders.
To set up a Parameter, use the CVARs app.Measure.Px.Sourcexand
app.Measure.Px.ParamEngine, plus any objects in the app.Measure.Px.Operator subfolder.
Labels
The CVARs LabelsText and LabelsPosition (which appear in the hierarchy for any waveform object)
specify the text and position of custom labels placed on a waveform. LabelsText takes a single String
argument for which you can specify a comma-delimited list of values each representing a separate label:
app.Acquisition.C1.LabelsText = "Hello,World"
The above control creates two labels, "Hello" and "World." Note that later sending the same control with
only a single value will erase all but the first label in the list (which will remain at its current position),
changing it to the new text string.
LabelsPosition is also a String where each list value is a pipe-delimited pair specifying the horizontal and
vertical position of the corresponding label in the LabelsText string. Placing parentheses around the
vertical value in the pair turns on "Use Trace Vertical Position". The following control would position both
labels "Hello" and "World", placing "Hello" adjacent to the trace, and "World" at the vertical position specified:
app.Acquisition.C1.LabelsPosition = "0.000002|(0.02),0.000002|0.01"
Colors
Color type CVARs set/query the color of traces and other display objects, using a number in the range 0 to
FFFFFF in hexadecimal. The possible colors are made from any combination of the primary colors, which
are set in hexadecimal as Blue = &HFF0000, Green = &HFF00, Red = &HFF. For example:
app.Display.C1Color = "255,255,0"
The value may be entered in decimal or in hexadecimal, though hexadecimal is usually more convenient.
Note that if the intensity of a color is to be reduced or increased by a numerical factor, an AND operation
must be used afterwards, to prevent corruption of other primary colors.
File Names
CVARs of the Filename type generally do not require the full path to be given as part of the value, but in
most cases, the directory in which the files will be saved is set using a separate CVAR, which does require
the full path. Check the parent objects within the subsystem in XStreamBrowser to find the CVAR for
setting the file path.
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Persistence
When applied to any trace, the CVARs Persisted,PersistDotJoined,Persistence3D,Persist3DQuality,
PersistenceMonochrome, and PersistenceSaturation determine the status and appearance of the
persistence display.
Persistence sets/queries the persistence state. If the Display.LockPersistence CVAR is set to 'AllLocked'
then the persisted state of all displayed waveforms will be the same. If the Display.LockPersistence
control is set to 'PerTrace' then the persisted state of each waveform may be independently controlled.
If PersistDotJoined is False (the default state), samples are put into the persistence map as dots. The
advantage of that is that any lit pixel in the pmap actually corresponds to a sample of the data taken at
that time. The disadvantage of dots is that there is no way to associate a dot with any other dot; there is no
history of which dots were part of the same acquisition. If this control is set True, then each acquisition
draws lines into the persistence map that connect the dots at the sample positions. Clearly the advantage
of that is that it is now possible to see if some outlier samples were all part of the same acquisition, or not.
The disadvantage is that lit points in the persistence map no longer correspond to actual samples, the
lines between the samples are also lit.
If the persistence map is going to be analyzed it is probably preferable to leave Dot Joined off so that only
actual samples are considered in the analysis. If there are very few points in a persistence map, there may
columns with no points, that is, there are gaps horizontally between points. In that case, Dot Joined will
connect them starting with the last trace, and for all subsequence traces accumulated.
The action of turning on or off Dot Joined clears the accumulated persistence map.
Persistence3D puts the persistence display into a 3D surface map.
Persistence3DQuality selects the 3D quality, which determines how the display is rendered. This CVAR is
only relevant when Persistence3D is True.
If PersistenceMonoChrome is set True, the display will be monochromatic, regardless of whether 2D or
3D.
Placeholders
In some cases, the value that appears in XStreamBrowser is only a placeholder that will appear on the
oscilloscope GUI until you make an actual setting. Placeholders will usually be indicated by angle brackets
surrounding the text string. For example, the Value of app.Utility.Remote.AllowControlFrom is <ipAddr, or
dnsName>, which appears inside the control on the GUI indicating you should substitute the remote client
IP address or DNS name. If you provided an actual IP address or DNS name, that node would have
exclusive remote control of the oscilloscope.
Serial Decoder Table Columns
The CVAR app.SerialDecode.Decodex.Decode.ColumnState contains a pipe-delimited list of all the table
columns that are selected for display. For example:
app.SerialDecode.Decode1.Decode.ColumnState = "Idx=On|Time=On|Data=On|..."
If you wish to change the table configuration by hiding or displaying columns, send the full string with the
state changed from "on" to "off", or vice versa, rather than remove any column from the list.
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Using Variables to Reference Objects
One way to increase the readability and simplicity of your source code is to use variables to reference
objects that are at each level of the hierarchy. For example, here is the VB code to read out the Sweeps
property for channel 1:
Dim numSweeps as Long
numSweeps = app.Acquisition.C1.Out.Result.Sweeps
If you are reading out more than just the Sweeps property, you might find it easier to read the following:
Dim C1Res as Object
Dim C1 as Object
Dim numSweeps as Long
Dim HorizontalOffset As Double
Dim HorizontalPerStep As Double
Dim VerticalOffset As Double
Dim VerticalPerStep As Double
Dim wform
C1 = app.Acquisition.C1
C1.AverageSweeps = 200 numSweeps = C1
Res.Sweeps HorizontalOffset = C1
Res.HorizontalOffset HorizontalPerStep = C1
Res.HorizontalPerStep VerticalOffset = C1
Res.VerticalOffset VerticalPerStep = C1
Res. VerticalPerStep
The panel setup files make heavy use of object variables, making them far more readable and editable:
Set Acquisition = XStreamDSO.Acquisition
Set C1 = Acquisition.C1
C1.View = True
C1.UseGrid = "YT1"
C1.Persisted = False
C1.PersistenceSaturation = 50
C1.PersistenceMonoChrome = True
C1.Persistence3d = False
...
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Part 2: Automation Programming Reference
Automation in MATLAB
On oscilloscopes equipped with the XDEV option, MATLAB applications can use Automation to exchange
data with the oscilloscope application. For more information, see Lab 831: X-Stream COM Object
Programming with MATLAB and Using LeCroy Digital Oscilloscopes with MATLAB.
Connecting and Disconnecting
MATLAB applications use the actxserver keyword to connect to the instrument. MATLAB supports
TCP/IP connections.
app = actxserver('LeCroy.XstreamDSO.1', '<IP address>')
Use 127.0.0.1 when running MATLAB on the oscilloscope, rather than accessing it remotely.
To disconnect, end with:
Set app = Nothing
Creating Object Variables
Given the complexity of MATLAB's syntax for handling multi-tiered Automation objects, it is highly
recommended to create object variables ("handles") at each level of the hierarchy. For example:
% creation of object variables 1 level down from top-level
acq = app.Object.Item('Acquisition');
math = app.Object.Item('Math');
meas = app.Object.Item('Measure');
PF = app.Object.Item('PassFail');
% creation of object variables 1 level further
c1 = acq.Object.Item('C1');
f1 = math.Object.Item('F1');
p1 = meas.Object.Item('P1');
p1Operator = p1.Object.Item('Operator')
% creation of object variables to results
c1_results = c1.Out.Result;
f1_results = f1.Out.Result;
p1_results = p1.Out.Result;
When using object variables, the code to access results and to get or set properties becomes much easier
to read and debug:
% Set some properties for P1 (assumes P1=per@level)
set(p1Operator, 'LevelType', 'Percent');
set(p1Operator, 'PercentLevel', 66);
set(p1Operator, 'Slope', 'Neg');
% Read back and display some results
p1_Val = p1_results.Value
p1_status = p1_results.Status
p1_time = p1_results.FirstEventTime
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MAUI Oscilloscopes Remote Control and Automation Manual
Accessing Control Variables (CVARs)
These instructions apply to CVARs (object selected from a yellow folder in XStreamBrowser).
Using the syntax:
<handle> = Object.Item('<object>')
Create an object variable for each level in the object hierarchy. For example, the following lines of code drill
into the hierarchy of the VerScale CVAR:
acq = app.Object.Item('Acquisition');
c1 = acq.Object.Item ('C1');
The result is a convenient set of handles to use rather than long and clumsy lines of code. Note that each
line above uses the object variable created in the line above it.
For CVARs that you can read or write, use the get and set functions to access properties of the CVAR. The
Value property is most frequently used, but others are available, including Range. Here are examples of
getting and setting the VerScale CVAR:
% read the value of the VerScale CVAR
C1VDiv = get(c1.Item('VerScale'), 'Value')
% read the Range and Type properties of the VerScale CVAR
range = get(c1.Item('VerScale'), 'Range')
type = get(c1.Item('VerScale'), 'Type')
% set VerScale to 0.789 V/div
set(c1.Item('VerScale'), 'Value', 0.789)
For CVARs that are Actions, use the invoke function:
% execute an application-level Clear Sweeps action
app.invoke('ClearSweeps','ActNow');
% execute an AutoSetup action
app.invoke('AutoSetup','ActNow');
% execute the ResetAll action for the Math system (only)
math.invoke('ResetAll','ActNow');
Action CVARs have an interface called ActNow that can be referenced, but this isn't required.
For CVARs that are Methods, use the invoke function and include the arguments required to perform the
method:
% execute the Acquire method with 5s timeout, no forced trigger
acq.invoke('Acquire', 5, false);
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Part 2: Automation Programming Reference
Accessing Out.Result Objects
These instructions apply to items that appear when selecting an object from a Result Interface folder in
XStreamBrowser.
For each level of the object hierarchy up to but not including the item’s parent object, create an object
variable using the syntax:
<handle> = Object.Item('<object>')
For example, the following lines of code drill into the P1 object hierarchy up to the parent "Out.Result":
meas = app.Object.Item('Measure');
p1 = meas.Object.Item('P1');
Create an object variable for "Out.Result" using this syntax:
p1_results = p1.Out.Result
To read properties within the Out.Result object, use either of the following:
p1_<handle> = p1_results.<property>
p1 = get(p1_results,'<property>')
For example, to read the Value property:
p1_val = p1_results.Value
Or
p1 = get(p1_results,'Value')
To read back multi-valued items such as ValueArray and DataArray, use the get function:
P1_array = get(p1_results, 'ValueArray', -1, 0, 1)
C1_data = get(c1_results, 'DataArray', -1, -1, 0, 1)
ValueArray, which returns all measured values for a parameter, and DataArray, which returns waveform
data, are actually interfaces that require several arguments to determine the number of values to return,
what kind of values, etc. See ValueArray and DataArray.
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MAUI Oscilloscopes Remote Control and Automation Manual
Automation in Python
The oscilloscope can be controlled by Automation from applications written in the Python language.
Python programs may be designed to execute locally using COM, or remotely using either the ActiveDSO
driver or a VISA driver. See the Python example in Remote Control Program Using VISA.
You will need the Python for Windows Extensions and Python installed wherever the program is to run. If it
runs locally, the libraries must be installed on the oscilloscope; if it connects remotely, they must be
installed on the controller. The version of Python for Windows Extensions should match your version of
Python.
For remote control, you will also need an installation of ActiveDSOor a VISA driver on the controller.
With COM
COM is the most direct way to send Automation commands to the oscilloscope in Python.
Note: Any COM program should be able to run from a remote computer that has a DCOM
connection to the oscilloscope.
Connecting
The initial connection imports the win32com.client, needed for any COM Automation, and any Python
extensions to be used. It then connects to the oscilloscope application, "LeCroy.XStreamDSO," here
aliased as "h":
import win32com.client
import matplotlib.pyplot as plt
h = win32com.client.Dispatch("LeCroy.XStreamDSO")
Accessing Control Variables
The current value of any CVARs (yellow folder objects) can be read by placing the object into a variable.
This example gets the current sample period of the variable "deltat", then prints it following the string
"Sample Period":
deltat = h.Acquisition.Horizontal.TimePerPoint
print "Sample Period = ", deltat
Shortcuts can be created to simplify references to any Automation object. This gets the vertical scale of
C1, using the shortcut c1 to refer to the full object path "h.Acquisition.C1":
c1 = h.Acquisition.C1
vdiv = c1.VerScale
print "Channel 1 Volts per Division Setting = ", vdiv
To change the setup of a CVAR, set the object (or its shortcut) equal to the new value:
c1.VerScale = .1
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Part 2: Automation Programming Reference
Accessing Out.Result Objects
To read a single measured property of a waveform, place the object (or its shortcut) into a variable:
numsamples = h.Acquisition.C1.Out.Result.Samples
print(numsamples)
To access the entire waveform, use the DataArray object. For example, to plot the C1 waveform:
wave = h.Acquisition.C1.Out.Result.DataArray
plt.plot(wave)
plt.show()
With ActiveDSO
For more examples, see the Technical Brief: Using Python with ActiveDSO for Remote Communication.
Connect and Disconnect
Connecting to the oscilloscope using ActiveDSO similarly calls the win32com.client then instantiates the
ActiveDSO control "LeCroy.ActiveDSOCtrl.1", here aliased as "scope". The MakeConnection string makes
the remote connection to the oscilloscope:
import win32com.client
scope=win32com.client.Dispatch("LeCroy.ActiveDSOCtrl.1")
scope.MakeConnection("<connection string>")
The <connection string> is whatever you would normally enter in the ActiveDSO MakeConnection method
to specify the interface, for example "IP: 172.0.0.31".
To disconnect, send:
scope.Disconnect()
Accessing Control Variables
For CVARs that you can read or write (yellow folder objects), use WriteString to send commands. The
<command string> is the remote command, either in the legacy 488.2 format, or an Automation control
sent within the VBS command.
scope.WriteString("<command string>", <Boolean EOI>)
For example, to set the C1 V/div to 20 mV using Automation, you would send:
scope.WriteString("""VBS 'app.Acquisition.C1.VDIV=".02 V" ' """, 1)
Note: The triple quotes around the command string are required because the double quotes
around the value ".02 V" are part of the Automation control embedded within the VBS command.
Otherwise, Python would interpret the first double quote as the end of the command string.
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MAUI Oscilloscopes Remote Control and Automation Manual
Accessing Out.Result Objects
To read Out.Result objects, use WriteString with the VBS? query (to access the result value) followed by
the ReadString method to return it in the desired format. The following code queries the result of the P1
parameter, reading a maximum of 80 bytes, and prints the results to the Interactive Window:
scope.WriteString("VBS? 'return=app.Measure.P1.Out.Result.Value' ",1)
value = scope.ReadString(80)
print(value)
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Part 2: Automation Programming Reference
Automation in C#
Newer programming languages like C# are not supported by the ActiveDSO control or the VICP protocol.
We recommend that those writing Automation programs in C# should do the following:
lConnect to the oscilloscope over ENET, either through your LAN or a direct connection.
lOn the oscilloscope, choose the LXI (VXI-11) remote control setting.
lOn the controller, install an VISA-compliant driver and the IVI C# VISA API to decouple your
Automation program from the driver.
The following C# program uses the above configuration to make a remote connection to the oscilloscope
and perform the same tasks as the Python script in Program Using VISA.
Note: Characters in angle brackets are placeholders. Omit the brackets from your code.
using System;
using Ivi.Visa;
namespace LeCroy.ScopeVisaExample
{
public class ScopeExample
{
public void DoExample()
{
// Open session to scope
var session = (IMessageBasedSession)GlobalResourceManager.Open
("TCPIP0::<hostname|IP address>::INSTR");
session.TimeoutMilliseconds = 5000;
session.Clear();
// Don't return command header with query result
session.FormattedIO.WriteLine("COMM_HEADER OFF");
// Recall default setup
session.FormattedIO.WriteLine("vbs 'app.settodefaultsetup'");
// Wait until scope is done with recall default
session.FormattedIO.WriteLine("vbs? 'return=app.WaitUntilIdle(5)'");
session.FormattedIO.ReadString();
// Set up acquisition trigger and timebase
session.FormattedIO.WriteLine("vbs 'app.acquisition.triggermode =
\"stopped\"'");
session.FormattedIO.WriteLine("vbs 'app.acquisition.trigger.edge.level =
1.0'");
session.FormattedIO.WriteLine("vbs 'app.acquisition.triggermode =
\"Single\"'");
session.FormattedIO.WriteLine("vbs 'app.acquisition.horizontal.maximize =
\"FixedSampleRate\"'");
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MAUI Oscilloscopes Remote Control and Automation Manual
// Clear all current measurement definitions and set up new measurement
session.FormattedIO.WriteLine("vbs 'app.measure.clearall'");
session.FormattedIO.WriteLine("vbs 'app.measure.showmeasure = true'");
session.FormattedIO.WriteLine("vbs 'app.measure.statson = true'");
session.FormattedIO.WriteLine("vbs 'app.measure.p1.view = true'");
session.FormattedIO.WriteLine("vbs 'app.measure.p1.paramengine = \"mean\"'");
session.FormattedIO.WriteLine("vbs 'app.measure.p1.source1 = \"C1\"'");
// Reset the parameter statistics
session.FormattedIO.WriteLine("vbs 'app.measure.clearsweeps'");
// Arm acquisition, forcing a trigger if there is none after 0.1 seconds.
// Take 10 acquisitions, find the mean value and print it to the console.
for (int i = 0; i < 10; ++i)
{
session.FormattedIO.WriteLine("vbs? 'return=app.acquisition.acquire
( 0.1 , True )'");
// Wait until all processing is done; check if timed out
session.FormattedIO.WriteLine("vbs? 'return=app.WaitUntilIdle(5)'");
var success = session.FormattedIO.ReadInt64();
if (success == 0)
{
throw new TimeoutException($"Time out from WaitUntilIdle, return =
{success}");
}
// Read result in P1 measurement parameter, write it to the console
session.FormattedIO.WriteLine("vbs?
'return=app.measure.p1.out.result.value'");
var mean = session.FormattedIO.ReadDouble();
Console.WriteLine($"Mean = {mean}");
}
// Close session and disconnect from scope
session.Dispose();
}
}
}
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Part 3: Automation Control Variable Reference
Part 3: Automation Control Variable Reference
This section describes the Actions and Methods that may be applied to XStream standard objects.
Many more CVARs are available in the XStream application than are documented here. Use
XStreamBrowser to view the entire app object hierarchy of your oscilloscope and the acceptable value
ranges for other types of CVARs. Also see the various software option manuals.
app 3-3
app.Acquisition 3-6
app.Acquisition.Cx 3-7
app.Acquisition.Trigger 3-8
app.Cursors 3-9
app.CustomDSO 3-10
app.Display 3-11
app.Hardcopy 3-12
app.History 3-13
app.LabNotebook 3-14
app.LogicAnalyzer 3-15
app.Math 3-16
app.Math.Fx and app.Math.XY 3-17
app.Measure 3-18
app.Measure.Px 3-19
app.Memory 3-20
app.PassFail 3-21
app.PassFail.Qx 3-22
app.Preferences 3-23
app.ProbesCal 3-24
app.SpecAnalyzer 3-25
app.SaveRecall 3-26
app.SaveRecall.Setup 3-27
app.SaveRecall.Utilities 3-28
app.TriggerScan 3-29
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Utility 3-30
app.WaveScan 3-31
app.WebEditor 3-32
app.Zoom 3-34
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Part 3: Automation Control Variable Reference
app
app is the root of the XStream automation hierarchy; all other nodes are accessed from this point.
Nested within the app object are the principal XStream subsystems. Standard and optional subsystems
are arranged alphabetically.
Child Objects
Object Description
app.Acquisition Subsystems related to the acquisition and digitization of signal: all
inputs, Timebase (Horizontal), and Trigger.
app.Cursors Cursor (measure) subsystem.
app.CustomDSO Custom DSO (XDEV) option. Standard on WavePro, WaveMaster, and
LabMaster oscilloscopes and equivalent DDA/SDA models.
app.Display Display subsystem.
app.DriveAnalysis Disk Drive Analyzer option. Standard on DDA model oscilloscopes.
app.EyeDr Eye Doctor II option. Standard on SDA model oscilloscopes with SDA III.
app.HardCopy Hardcopy (Print) subsystem.
app.Help Online Help subsystem.
app.History History Mode subsystem.
app.LabNotebook LabNotebook subsystem.
app.Math Math (Function) subsystem.
app.MotorDriveAnalysis Motor Drive Analyzer option. Standard on MDA800 oscilloscopes.
app.Measure Measure (Parameter) subsystem.
app.Memory Internal memory (storage) subsystem.
app.OMA Optical Modulation Analysis option. Standard on OMA systems.
app.PassFail Pass/Fail testing subsystem.
app.Preferences Application preferences subsystem.
app.ProbesCal Probe calibration subsystem.
app.SaveRecall Save Recall (File) subsystem.
app.SDA2 or app.SDA3 SDA II and SDA III options. Standard on SDA model oscilloscopes.
app.SpecAnalyzer Spectrum Analyzer option. Standard on HDO6000, HDO8000, and
MDA800 oscilloscopes.
app.SystemControl Mouse/pointer control subsystem.
app.TriggerScan TriggerScan subsystem.
app.Utility Utilities subsystem.
app.VirtualProbe Virtual Probe option. Standard on SDA model oscilloscopes with SDA III.
app.WaveScan WaveScan subsystem.
app.WebEditor WebEditor subsystem.
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MAUI Oscilloscopes Remote Control and Automation Manual
Object Description
app.XPort Report output subsystem.
app.Zoom Zoom ("expansion trace") subsystem.
Actions
Action Description
app.AutoSetup Starts an AutoSetup operation. When input channels are visible,
AutoSetup operates only on those visible channels. If no channels are
visible, all channels are affected by AutoSetup. With more than one
channel visible, the first visible channel in numerical order that has a
detectable signal applied to it is automatically set up for edge triggering.
app.ClearSweeps Clears all accumulated sweeps for all subsystems. These include
Channel Pre-Processing, Math,Measure, and Display Persistence. Note
that subsystem-specific ClearSweeps controls affect only the individual
subsystem.
app.Exit Equivalent to app.Quit() method.
app.FindAllVerScaleAtCurrentTimebase Rescales all channel traces to occupy most of the full vertical scale
range, but without changing the timebase. A better adjustment will be
made if Var Gain is also enabled, in which case the traces will be adjus-
ted to occupy +/- 3.3 divisions.
app.Maximize Maximizes window to fill desktop. Equivalent to app.WindowState = 1.
app.Minimize Minimizes window to reveal underlying desktop. It will display a small
window in the corner of the display that when clicked restores the
window to full-screen mode. To programmatically restore the window,
refer to app.WindowState.
app.ResetPreferences Resets all application preferences to their default states. This includes
the remote communications port, the color palette settings, etc. but does
not include controls such as V/Div, T/Div, etc. These main instrument
controls can be reset using the SetToDefaultSetup control.
app.Restore Restores the instrument display to its position and size before the last
minimize request.
app.SetToDefaultSetup Restores all instrument panel setups to the factory default state. User
preference settings such as the remote communications port, color
palette, etc. will not be restored to the default state. These may be reset
using the ResetPreferences action.
app.Shutdown Powers off the instrument. User will be prompted to confirm. Until the
user responds, control via Automation is blocked.
app.Windowed Places the application window in the upper-part of the display screen
with a sizable border.
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Part 3: Automation Control Variable Reference
Methods
app.Quit
Closes the XStream application. User will be prompted to confirm. Until the user responds, control via
Automation is blocked.
app.Sleep([in] double timeoutMilliseconds)
Causes the main execution thread of the instrument application to sleep for the specified time period,
defined in milliseconds.
' Sleep for ten seconds
app.Sleep(10000)
WaitUntilIdle([in] double timeoutSeconds)
Waits until either the application is idle or the specified timeout expires, specified in seconds. This
evaluates to True if the application completes before the timeout expires, and to False if a timeout occurs.
When Trigger mode is Auto or Run, the application is never Idle. In this case the call to WaitUntilIdle returns
after the next acquisition and any configured processing.
' Wait with a timeout of five seconds
app.WaitUntilIdle(5)
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Acquisition
CVARs related to inputs C1-Cxand Aux In, the timebase, the trigger, and the Aux Output.
Child Objects
Object Description
app.Acquisition.AuxIn Aux In settings.
app.Acquisition.AuxOutput Aux Out settings.
app.Acquisition.CxChannel inputs C1 to Cx. The number depends on your oscilloscope
model.
app.Acquisition.Horizontal Acquisition timebase settings.
app.Acquisition.Trigger Acquisition trigger settings.
Actions
Action Description
app.Acquisition.Calibrate Initiates a full calibration of the acquisition system of the instrument.
app.Acquisition.ClearSweeps Resets any accumulated average data or persistence data for channel
waveforms. Valid only when one or more channels have waveform
averaging or persistence enabled in their pre-processing settings. Note
that channel counters may be reset on an individual basis using
app.Acquisition.Cx.ClearSweeps control.
app.Acquisition.CopyChannelSetup Launches the Copy Channel Setup modal dialog for making the copy
selections. Equivalent to clicking Copy Channel Setup button.
app.Acquisition.ShowChannelSetup Opens the Channel Setup dialog, which summarizes all the channel Ver-
tical settings.
app.Acquisition.AuxOutput.SetToDefault Sets the Aux Output controls to their default values.
Methods
app.Acquisition Acquire([in] double timeoutSeconds, [in] long bForceTriggerOnTimeout)
Takes a single acquisition. The first of the two arguments specifies a timeout; the second, which is
optional, specifies whether or not to force a trigger when the timeout occurs. Evaluates to True if a trigger
occurred, or False if a timeout occurred.
' Start acquisition, wait 5 seconds for trigger, force trigger if not detected
within 5 seconds
triggerDetected = app.Acquisition.Acquire(5, true)
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Part 3: Automation Control Variable Reference
app.Acquisition.Cx
CVARs related to input channels C1 through Cx.
Names of the form app.Acquisition.Channels.xxxx are an alias Collection. For example:
lapp.Acquisition.Channels("Cx") is equivalent to app.Acquisition.Cx
lapp.Acquisition.Channels(1) is equivalent to app.Acquisition.C1
lapp.Acquisition.Channels("Cx").Out.Result is equivalent to app.Acquisition.Cx.Out.Result
Child Objects
Object Description
app.Acquisition.Cx.InputB On WaveMaster, LabMaster, and equivalent DDA/SDA oscilloscopes,
settings related to the "B" row inputs.
Actions
Action Description
app.Acquisition.Cx.ClearSweeps Clears all accumulated sweeps for channel.
app.Acquisition.Cx.FindScale Automatically adjusts channel's V/div and Offset such that the signal is
visible on the screen within +/- 3 div.
app.Acquisition.Cx.HorScaleToggle Toggles Horizontal Offset control between (1, 2, 5) stepped and fine
increment input. Var. checkbox is cleared or checked.
app.Acquisition.Cx.VerScaleToggle Toggles Vertical Scale control between (1, 2, 5) stepped and fine incre-
ment input. Var. checkbox is cleared or checked.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Acquisition.Trigger
CVARs related to acquisition trigger.
Child Objects
Object Description
app.Acquisition.Trigger.<Type> Currently selected acquisition trigger type
(e.g., app.Acquisition.Trigger.Edge). The settings within the <Type>
object will change depending on what is selected. Most trigger types sup-
port the Action FindLevel.
app.Acquisition.SoftwareAssistedTrigger Settings related to Software Assisted Trigger feature. Not available on
WaveSurfer and HDO4000 oscilloscopes.
Actions
Action Description
app.Acquisition.Trigger.<Type>.FindLevel Automatically sets trigger level to signal mean.
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Part 3: Automation Control Variable Reference
app.Cursors
CVARs related to the selection and placement of measurement cursors.
Child Objects
Object Description
app.Cursors.XYCursorsMgr Settings related to the placement and tracking of relative cursors.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.CustomDSO
CVARs related to the CustomDSO (XDEV) option. Standard on WavePro, WaveMaster, and LabMaster
oscilloscopes.
Actions
Action Description
app.CustomDSO.PlugIn1Install Installs custom program
app.CustomDSO.PlugIn1Remove Removes custom program
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Part 3: Automation Control Variable Reference
app.Display
CVARs related to the oscilloscope touch screen display and the appearance of waveform traces.
Actions
Action Description
app.Display.ClearSweeps Clears sweeps only for persistence traces.
app.Display.DisableExternalMonitor Exit external monitor display; resume default touch screen display.
app.Display.EnableExternalMonitor Enter external monitor display.
app.Display.FactoryDefault Equivalent to SetToDefault.
app.Display.OpenMonitorControls Opens dialog for external monitor setup.
app.Display.PreviewPrintColors Shows the instrument display in the currently selected print color palette.
app.Display.ResetAll Turns off display persistence on any trace where it has been set.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Hardcopy
CVARs related to the oscilloscope Print function. This includes hardcopy print as well as print to file, send
to email, and copy to clipboard.
Actions
Action Description
app.Hardcopy.EjectPaper Sends eject command to connected printer. This action is only relevant if
app.Hardcopy.Destination is set to Printer.
app.Hardcopy.Print Initiates the print action; opens modal dialog for completing print
selections.
app.Hardcopy.PrintToRemote Performs the same action as the above command, but useful for pro-
gramming languages where ending a command with the word "print" is
problematic.
app.Hardcopy.ShowEmailMenu Displays dialog for configuring Email settings.
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Part 3: Automation Control Variable Reference
app.History
CVARs related to the oscilloscope History Mode feature.
Child Objects
Object Description
app.History.HistoryTable Settings related to the History Mode tabular display.
Actions
Action Description
app.History.Next Displays next acquisition in history.
app.History.Previous Displays previous acquisition in history.
app.History.HistoryTable.ClearSweeps Clears history buffer.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.LabNotebook
CVARs related to the LabNotebook documentation tool.
Actions
Action Description
app.LabNotebook.BackupDatabase Backs up the current Notebook. This control will present a modal
dialog, prompting for the backup file name and folder. Use the
BackupToFolder control to skip the dialog.
app.LabNotebook.BackupToFolder Backs up the current Notebook into the path specified by
theBackupFolder and BackupFilename controls.
app.LabNotebook.BackupToMemoryStick Backs up the current Notebook onto an external USB memory
drive.
app.LabNotebook.Cancel Cancels creation/edit of Notebook Entry.
app.LabNotebook.ClearFilter Clears selection filter on list of Notebook Entries.
app.LabNotebook.CompactDatabase Creates compacted bak.zip file of the selected Notebook.
app.LabNotebook.CreateReport Outputs selected Notebook Entries in report format.
app.LabNotebook.DeleteAll Deletes all Notebook Entries.
app.LabNotebook.DeleteNotebook Deletes selected Notebooks.
app.LabNotebook.DeleteRecord Deletes selected Notebook Entries.
app.LabNotebook.EmailRecord Emails selected Notebook Entries.
app.LabNotebook.FilterRecords Applies search filters to list of Notebook Entries.
app.LabNotebook.FlashBackToRecord Invokes Flashback Recall of selected Notebook Entry. The flash-
back restores the screen image, waveforms, and setups saved
with the entry.
app.LabNotebook.NextRecord Displays the next Notebook Entry
app.LabNotebook.PreviousRecord Displays the previous Notebook Entry
app.LabNotebookPrintRecord Sends selected Notebook Entry to connected printer.
app.LabNotebook.Save Saves current state of oscilloscope to new Notebook Entry.
app.LabNotebook.ViewRecord Displays selected Notebook Entry in report window.
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Part 3: Automation Control Variable Reference
app.LogicAnalyzer
CVARs related to digital logic analyzer functions. Standard on -MS/MSO model oscilloscopes, or with an
optional external Mixed-Signal input device.
Child Objects
Object Description
app.LogicAnalyzer.DigitalxDigital logic group settings.
app.LogicAnalyzer.Pattern Custom logic pattern settings.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Math
CVARs related to Math functions F1-Fx.
Names of the form app.Math.Functions("Fx").xxxx are an alias Collection. For example:
lapp.Math.Functions("Fx") is equivalent to app.Math.Fx
lapp.Math.Functions("Fx").Out.Result is equivalent to app.Math.Fx.Out.Result
lapp.Math.Functions("Fx").Zoom is equivalent to app.Math.Zoom.Fx
Child Objects
Object Description
app.Math.FxMath functions F1 to Fx.
app.Math.XY CVARs controlling the display of data in X vs. Y mode. Only Valid when
the instrument is in XY, XYSingle, or XYDual display modes.
Actions
Action Description
app.Math.ClearSweeps Clears sweeps for history functions such as average, histogram and
trend.
app.Math.ResetAll Resets all math functions to default state; all function definitions are
cleared.
app.Math.ShowZoomMenu Displays the Zoom dialog for rescaling functions.
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Part 3: Automation Control Variable Reference
app.Math.Fxand app.Math.XY
CVARs related to individual math functions F1-Fxand XY trace.
Child Objects
Object Description
app.Math.Fx.OperatornSetup This node is dynamically created and will contain the controls for the
operator currently selected into Operatorn.
app.Math.Fx.Zoom Function zoom scale settings.
Actions
Action Description
app.Math.Fx.ClearSweeps
app.Math.XY.ClearSweeps
Clears accumulated data for single function trace.
Clears persistence X-Y plot.
app.Math.Fx.DoResetZoom Resets scale of Fxtrace to 1:1.
app.Math.Fx.DoStoreToMemoryTrace Stores Fxtrace to corresponding internal memory (e.g., F1 to M1).
app.Math.Fx.FPHit Opens/closes the Fxdialog display. Each successive invocation of the
command acts like a toggle.
app.Math.Fx.ShowProcessingWeb Open WebEditor window to create processing web to run in function.
Not available on WaveSurfer and HDO4000 oscilloscopes.
app.Math.Fx.OperatornSetup.DownFactor For those operators that involve a sampling factor (such as Inter-
polation), decreases the sample value by one step.
app.Math.Fx.OperatornSetup.UpFactor For those operators that involve a sampling factor (such as Inter-
polation), increases the sample value by one step.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Measure
CVARs related to Measure parameters P1-Px(MyMeasure mode) and the statistical results and histicons
which depend on them.
Names of the form app.Measure.Measure("Px").xxxx are an alias Collection. For example:
lapp.Measure.Measure("Premote").OutResult is equivalent to app.Measure."Premote".OutResult
lapp.Measure.Measure("Px").Statistics is equivalent to app.Measure.Px.Statistics
Child Objects
Object Description
app.Measure.PxUser-defined measure parameters P1 to Px.
app.Measure.PRemote
Actions
Action Description
app.Measure.ClearAll Resets all parameter setups, turning each of the parameters view to "off",
the MeasurementType to "measure"and the selected paramEngine to
"Null".
app.Measure.ClearAllHelpMarkers Force off all 'HelpMarkers'. HelpMarkers are the on-trace annotation of
measurement setup and results.
app.Measure.ClearSweeps Clears the accumulated statistics for parameters P1 to Pxas well as the
acumulated statistics for their associated histicons.
app.Measure.SetGateToDefault Sets the measure gate to its default state(-5 to 5 Div). Valid only when in
either Std. Vertical or Std. Horizontal measurement modes. For MyMeas-
ure, see the equivalent controls under app.Measure.Px.
app.Measure.ShowAllHelpMarkers Force on all 'HelpMarkers'.
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Part 3: Automation Control Variable Reference
app.Measure.Px
CVARs related to individual measure parameters P1-Px.
Child Objects
Object Description
app.Measure.Px.Accept Measurement result filter settings.
app.Measure.Px.Operator Settings related to selected measurement.
Actions
Action Description
app.Measure.Px.HistogramThis Draws histogram plot of measurement results.
app.Measure.Px.ShowProcessingWeb Opens Web Editor window to create processing web to run in parameter.
Not available on WaveSurfer and HDO4000 oscilloscopes.
app.Measure.Px.TrackThis Draws track plot of measurement results.
app.Measure.Px.TrendThis Draws trend plot of measurement results.
app.Measure.Px.Accept.FindLevel Automatically sets filter level based on signal characteristics.
app.Measure.Px.Accept.FindRange Automatically sets filter level range based on signal characteristics.
app.Measure.Px.Operator.FindLevel Automatically finds measurement level based on signal characteristics.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Memory
CVARs related to the internal memories M1 through Mx.
Names of the form app.Memory.Memories("Mx").xxxx are an alias Collection. For example:
lapp.Memory.Memories("Mx").Out.Result is equivalent to app.Memory.Mx.Out.Result
lapp.Memory.Memories("Mx").Zoom is equivalent to app.Memory.Mx.Zoom
Child Objects
Object Description
app.Memory.MxInternal memories M1 to Mx.
Actions
Action Description
app.Memory.ClearAllMem Clears the contents of all trace memories.
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Part 3: Automation Control Variable Reference
app.PassFail
CVARs related to Pass/Fail testing and test Qualifiers Q1-Qx.
Names of the forms app.PassFail.PassFail("Qremote").xxxx and app.PassFail.PassFail("Qx").xxxx are alias
Collections. For example:
lapp.PassFail.PassFail("Qremote").Operator is equivalent to app.PassFail.Qremote.Operator
lapp.PassFail.PassFail("Qx").Out.Result is equivalent to app.PassFail.Qx.Out.Result
Child Objects
Object Description
app.PassFail.QxSettings related to test qualifier.
app.PassFail.LastPass Returns last passed result. See Result Interface reference.
app.PassFail.NumPass Returns number of results passed. See Result Interface reference.
app.PassFail.Rate Returns Pass Fail rate. See Result Interface reference.
Actions
Action Description
app.PassFail.ClearSweeps Clears accumulated data for single function trace.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.PassFail.Qx
CVARs related to individual Pass/Fail test qualifiers Q1-Qx. Not available on WaveSurfer and HDO4000
oscilloscopes.
Child Objects
Object Description
app.PassFail.Qx.Operator Settings related to test operator.
Actions
Action Description
app..PassFail.Qx.ClearSweeps Clears sweeps.
app..PassFail.Qx.Operator.ClearSweeps Clears sweeps.
app.PassFail.Qx.Operator.FindLimit When qualifier is performing a parameter comparison
(Condition = Param compare), sets the maximum value in
Operator Limit field.
app.PassFail.Qx.Operator.FindLimitUsingnSigma When qualifier is performing a parameter comparison
(Condition = Param compare), sets the value in Operator
Limit field using nSigma. n:= {1, 3, 5}
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Part 3: Automation Control Variable Reference
app.Preferences
This set of CVARs controls user preferences for the instrument setup and operation.
Child Objects
Object Description
app.Preferences.Display Touch screen display behavior preferences.
app.Preferences.Email Email preferences.
Actions
Action Description
app.Preferences.Display.OpenMonitorControls Open Windows display panel for internal/external monitor configuration.
app.Preferences.Display.PreviewPrintColors Opens preview window of image using print color palette.
app.Preferences.Display.ResetAll Returns all display settings to factory default.
app.Preferences.Email.ComposeMail Launches dialog to compose cover email when file "printed" to email.
app.Preferences.Email.SendMail Sends email message.
app.Preferences.Email.SendTestMail Sends a message by e-mail to test the system.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.ProbesCal
CVARs related to probe calibration feature. Not available on WaveSurfer and HDO4000 oscilloscopes.
Actions
Action Description
app.ProbesCal.CalibrateAllnInitiates full calibration of corresponding channel n, which includes
Gain/Offset, and deskew.
app.ProbesCal.ClearnClears all calibration coefficients for corresponding channel n.
app.ProbesCal.DcCalnInitiates a DC calibration (Gain/Offset) of corresponding channel n.
app.ProbesCal.DeskewnInitiates a deskew calibration of corresponding channel n.
app.ProbesCal.RecallCalSetup Whenever a probe calibration is applied, the scope saves the inform-
ation in a file on the disk. If the scope must be rebooted for any reason,
the probe calibration information is always cleared, but can be recalled
using this control.
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Part 3: Automation Control Variable Reference
app.SpecAnalyzer
CVARs related to the Spectrum Analyzer option. Standard on HDO6000, HDO8000, and MDA800 series
oscilloscopes.
Child Objects
Object Description
app.SpecAnalyzer.SpecAn Post-processing spectrum trace.
app.SpecAnalyzer.SpecAnTable Spectrum measurement table.
app.SpecAnalyzer.Spectro Spectrogram plot.
app.SpecAnalyzer.SpecWindow Spectrum Analyzer window.
app.SpecAnalyzer.SpIn Spectrum source trace.
Actions
Action Description
app.SpecAnalyzer.AllMarkersOff Turns off all markers.
app.SpecAnalyzer.MarkerToCenterFreq Moves marker to center frequency.
app.SpecAnalyzer.MarkerToRefLevel Moves marker to reference level.
app.SpecAnalyzer.SetDefaultMarkers Places default markers on SpecAn trace.
app.SpecAnalyzer.SetHarmonicsMarkers Places harmonic frequency markers on SpecAn trace.
app.SpecAnalyzer.SetPeaksMarkers Places peaks markers on SpecAn trace.
app.SpecAnalyzer.SpecAn.ClearSweeps Clears any accumulated result data for SpecAn trace.
app.SpecAnalyzer.SpecAnTable.ClearSweeps Clears any accumulated result data used in computation of
SpecAn table.
app.SpecAnalyzer.Spectro.ClearSweeps Clears any accumulated result data for spectrogram plot.
app.SpecAnalyzer.SpecWindow.ClearSweeps Clears any accumulated result data for "window" of gated spec-
trum trace.
app.SpecAnalyzer.SpIn.ClearSweeps Clears any accumulated result data for spectrum source trace.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.SaveRecall
CVARs related to saving or recalling setups, waveforms, and tabular data.
Child Objects
Object Description
app.SaveRecall.Remote Controls defining the scope and format of exported waveform data.
app.SaveRecall.Setup Controls related to setup panel data.
app.SaveRecall.Table Controls related to table data.
app.SaveRecall.Utilities Controls related to the file directory structure.
app.SaveRecall.Waveform Controls related to waveform data.
Actions
Action Description
app.SaveRecall.Table.DoSave Save displayed table data to .CSV file.
app.SaveRecall.Waveform.DoRecall Recall waveform (.TRC) file into internal Memory.
app.SaveRecall.Waveform.DoSave Save waveform to internal Memory or to (.TRC) file.
app.SaveRecall.Waveform.NextFile Display next .TRC file in directory.
app.SaveRecall.Waveform.PrevFile Display previous .TRC file in directory.
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Part 3: Automation Control Variable Reference
app.SaveRecall.Setup
CVARs related to saving or recalling setup data.
Actions
Action Description
app.SaveRecall.Setup.DoRecallDefaultNvlPanel Recalls the factory set NVL (preference) panel settings. These are con-
trols which are not affected when the default panel is recalled, and
includes items such as the color preferences, remote control pref-
erences, etc. Use with care, especially when invoking over a remote
connection, as it could result in the controller being disconnected
when the default port is selected.
app.SaveRecall.Setup.DoRecallDefaultPanel Recalls factory default panel settings. Equivalent to pressing Default
Setup or Recall Default button.
app.SaveRecall.Setup.DoRecallPanel Recalls setup from internal panel
app.SaveRecall.Setup.DoRecallSetupFileDoc2 Recalls setup from selected .LSS file.
app.SaveRecall.Setup.DoSavePanel Saves setup to internal panel.
app.SaveRecall.Setup.DoSavePanelWithPrompt Saves setup to .LSS file with prompt for file name.
app.SaveRecall.Setup.DoSaveSetupFileDoc2 Saves setup to autogenerated .LSS file.
app.SaveRecall.Setup.RecallInternalnRecall setups in corresponding internal panel.
app.SaveRecall.Setup.SaveInternalnSave current setup to corresponding internal panel.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.SaveRecall.Utilities
CVARs related to file directory structure.
Actions
Action Description
app.SaveRecall.Utilities.CopyDir Copies all files from path set in app.SaveRecall.Utilities.Directory
app.SaveRecall.Utilities.CopyFile Copies file in path app.SaveRecall.Utilities.SelectedFiles
app.SaveRecall.Utilities.CreateDir Creates path set in app.SaveRecall.Utilities.DestDirectory
app.SaveRecall.Utilities.DeleteAll Deletes all files from path set in app.SaveRecall.Utilities.Directory
app.SaveRecall.Utilities.DeleteFile Deletes file from path set in app.SaveRecall.Utilities.SelectedFiles
app.SaveRecall.Utilities.EmailSelectedFilesNow Emails files from path set in
app.SaveRecall.Utilities.SelectedFiles
app.SaveRecall.Utilities.NextFile Shows next file in path set in app.SaveRecall.Utilities.Directory
app.SaveRecall.Utilities.PrevFile Shows prev. file in path set in app.SaveRecall.Utilities.Directory
app.SaveRecall.Utilities.SaveSelectedFilesToZipNow Zips files in path set in app.SaveRecall.Utilities.SelectedFiles
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Part 3: Automation Control Variable Reference
app.TriggerScan
CVARs related to the TriggerScan feature. Not available on WaveSurfer and HDO4000 oscilloscopes.
Actions
Action Description
app.TriggerScan.AddNewSetup Appends the current trigger setup to the list of TriggerScan triggers.
app.TriggerScan.DeleteAll Deletes all stored trigger setups from the trigger list.
app.TriggerScan.DeleteSelected Deletes the selected trigger setup from the trigger list.
app.TriggerScan.LoadSelected Loads the trigger setup selected in the trigger list into the current trigger
setup.
app.TriggerScan.LoadSetup Loads the trigger list from the file specified in the SetupFileName control.
app.TriggerScan.SaveSetup Saves the current trigger list into the file specified in the SetupFileName
control.
app.TriggerScan.StartScan Starts scanning. Places the scope in Normal trigger mode, and starts
walking down the list of trigger setups.
app.TriggerScan.StartTraining Starts training. This will take an acquisition on the channel specified in
the TrainerSource control, and depending upon the state of the
TrainEdges, TrainGlitches, TrainIntervals, TrainRunts, TrainWidths con-
trols, creates a list of trigger setups.
app.TriggerScan.StopScan Stops scanning.
app.TriggerScan.UpdateSelected Updates the currently selected TriggerScan setup with the current trigger
setup.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Utility
CVARs related to oscilloscope utilities.
Child Objects
Object Description
app.Utility.DateTimeSetup Data/Time controls.
app.Utility.Options Option key installation/activation controls.
app.Utility.Remote Remote control settings.
Actions
Action Description
app.Utility.DateTimeSetup.AddOneHour Adds one hour to current time.
app.Utility.DateTimeSetup.BackOneHour Removes one hour from current time.
app.Utility.DateTimeSetup.SetFromSNTP Sets the real time clock from the simple network time pro-
tocol.
app.Utility.DateTimeSetup.ShowProperties Launches modal dialog showing current date/time settings.
app.Utility.DateTimeSetup.Validate Validates any new settings. This action is equivalent to click-
ing 'Validate Changes' on the Date/Time page.
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Part 3: Automation Control Variable Reference
app.WaveScan
CVARs related to the WaveScan feature. Not available on WaveSurfer and HDO4000 oscilloscopes.
Child Objects
Object Description
app.WaveScan.ScanDecode Scan Decode table view controls.
app.WaveScan.ScanHisto Scan Histogram view controls.
app.WaveScan.ScanOverlay Scan Overlay (marker) view controls.
Actions
Action Description
app.WaveScan.FindRarenSigma Presets the filter limit and delta to find rare events. Uses the his-
tory of measurements since the last Clear Sweeps, or control
change, to set the limit and delta to capture +/- nsigma events. n:=
{1,3,5}
app.WaveScan.FindSelectRarest Presets the filter to find rarest event in acquisition.
app.WaveScan.FindUseMean Setup the filter to find measurements with values > the current stat-
istical mean.
app.WaveScan.ScanDecode.ClearSweeps Clears any accumulated result data.
app.WaveScan.ScanHisto.ClearSweeps Clears any accumulated result data.
app.WaveScan.ScanHisto.Histogram.ClearSweeps Clears any accumulated result data.
app.WaveScan.ScanHisto.Histogram.FindScale Automatically determine an appropriate horizontal scale for the
histogram, using the values currently in the histogram buffer.
app.WaveScan.ScanHisto.Zoom.ResetZoom Resets the zoom settings to their default values.
app.WaveScan.ScanOverlay.ClearSweeps Clears any accumulated result data.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.WebEditor
CVARs related to the WebEditor, which is used to create custom processing chains ("webs") associated
with a single function, parameter, or Pass/Fail qualifier.
Actions
Action Description
app.WebEditor.ClearSweeps Clears any accumulated data for nodes such as Average, Persistence,
etc. that reside in the processing web.
Methods
app.WebEditor.AddConnection([in] VARIANT destProcessor, [in] VARIANT destInputPin, [in] VARIANT
sourceProcessor, [in] VARIANT sourceOutputPin)
Adds a connection between two 'pins' of nodes placed within the Web Editor. Pins are described by the
name of the node, and the zero-based index of the pin on that node.
app.WebEditor.AddPreview([in] VARIANT sourceProcessor, [in] VARIANT sourcePin, [in] BSTR
previewName, [in] double xPosition, [in] double yPosition, [in] BSTR associatedExecName)
Adds a Preview to the specified pin of the specified node. The coordinates specify where the preview will
appear on the Web, with 0,0 being the top left-hand corner.
app.WebEditor.AddProcessor([in] VARIANT processorOrClassId, [in] BSTR requestedName, [in] double
xPosition, [in] double yPosition)
Adds a named 'processor' to the web. To determine the name of a processor just place it on the web using
the GUI and hover the mouse over the node. The 'ProgID' of the node, in the format LeCroy.<procName>'
will appear. Note that when adding processors from automation there is no distinction between Measure,
Math, and Pass/Fail processors.
' Create a Waveform Averager, name it "MyAvg", and place it at x=200, y=30
app.WebEditor.AddProcessor "LeCroy.Average", "MyAvg", 200, 30
app.WebEditor.GetProcessor([in] VARIANT processor)
Retrieves a reference to a processor that has been added to the Web. This reference may then be used to
access the processor's controls.
' Retrieve a pointer to the MyAvg averager and set it's number of sweeps
to the value 1234
set myAverager = app.WebEditor.GetProcessor("MyAvg")
myAverager.Sweeps = 1234
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Part 3: Automation Control Variable Reference
app.WebEditor.RemoveAll()
Removes all processors from the web.
' Show the WebEditor and remove all processors from it
app.ActiveView = "WebEdit"
app.WebEditor.RemoveAll
app.WebEditor.RemoveConnection([in] VARIANT destProcessor, [in] VARIANT destInputPin)
Removes a connection between two pins on the web.
app.WebEditor.RemovePreview([in] VARIANT processor)
Removes the named preview display.
app.WebEditor.RemoveProcessor([in] VARIANT processor)
Removes the named processor from the Web.
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MAUI Oscilloscopes Remote Control and Automation Manual
app.Zoom
CVARs related to Zoom (Zx) traces.
Child Objects
Object Description
app.Zoom.Zx Zooms Z1 to Zx. The number depends on your oscilloscope model.
Actions
Action Description
app.Zoom.GoToEnd When in MultiZoom mode, scroll to the end of the source waveform,
whose last point will be centered on the graticule.
app.Zoom.GoToStart When in MultiZoom mode, scroll to the start of the source waveform,
whose first point will be centered on the graticule.
app.Zoom.HorZoomIn Horizontally zoom in all the traces included in MultiZoom.
app.Zoom.HorZoomOut Horizontally zoom out all the traces included in MultiZoom.
app.Zoom.ResetAll Reset all zoom traces to their default settings.
app.Zoom.ResetZoom Resets the general zoom settings to their default values.
app.Zoom.Zx.ClearSweeps Clears any accumulated result data for individual zoom trace Zx.
app.Zoom.Zx.DoStoreToMemoryTrace Stores the content of Zxinto the corresponding memory (Mx).
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Part 4: Automation Result Interface Reference
Part 4: Automation Result Interface Reference
The following result interfaces (Out.Result objects) appear throughout the XStream object hierarchy.
Their properties will generally be the same regardless of which subsystem to which they apply.
Base 4-4
BinPopulations 4-4
Bins 4-4
BinWidth 4-5
BusName 4-5
CellType 4-5
CellValue 4-6
Columns 4-6
DataArray 4-7
ExtendedStatus 4-10
FirstEventTime 4-11
FirstPopulatedBin 4-11
HorizontalFrameStart 4-12
HorizontalFrameStop 4-12
HorizontalOffset 4-12
HorizontalPerColumn 4-12
HorizontalPerStep 4-13
HorizontalResolution 4-13
HorizontalUnits 4-13
HorizontalVarianceArray 4-13
HorizontalVariances 4-13
IndexOfFirstSampleInFrame 4-14
LastEventTime 4-14
LastPopulatedBin 4-14
Levels 4-14
LineAliasName 4-14
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MAUI Oscilloscopes Remote Control and Automation Manual
LineName 4-15
Lines 4-15
Max 4-15
MaxPopulation 4-15
MaxPopulationBin 4-15
MaxPopulationInRectangle 4-16
Mean 4-16
Min 4-16
NumFrameDimensions 4-17
NumSamplesInFrame 4-17
OffsetAtLeftEdge 4-17
Peaks 4-18
PeakInfo 4-18
PopulationInside 4-19
PopulationOfRectangle 4-19
PopulationOver 4-19
PopulationUnder 4-20
RMS 4-20
Rows 4-20
Samples 4-20
Sdev 4-20
Status 4-21
StatusDescription 4-22
Sweeps 4-23
Top 4-23
UniformInterval 4-23
UpdateTime 4-23
Value 4-24
ValueArray 4-25
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Part 4: Automation Result Interface Reference
VerticalFrameStart 4-26
VerticalFrameStop 4-26
VerticalMaxPossible 4-26
VerticalMinPossible 4-26
VerticalOffset 4-26
VerticalPerRow 4-27
VerticalPerStep 4-27
VerticalResolution 4-27
VerticalUnits 4-27
XFrameStart 4-27
XFrameStop 4-28
XMaxPossible 4-28
XMinPossible 4-28
XOffset 4-28
XPerStep 4-28
XResolution 4-29
XUnits 4-29
YFrameStart 4-29
YFrameStop 4-29
YMaxPossible 4-29
YMinPossible 4-30
YOffset 4-30
YPerStep 4-30
YResolution 4-30
YUnits 4-30
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MAUI Oscilloscopes Remote Control and Automation Manual
Base
Horizontal coordinate of the leftmost of the two most populated histogram peaks. It is equivalent to the
paramater hbase.
Applies to: Histogram
Dim hbase as Double
hbase = app.Math.F1.Out.Result.Base
BinPopulations
Variant array containing the populations of each bin. Bin 0 is the first bin. Index the array to retrieve the
number of counts in a given bin.
Applies to: Histogram
Read out BinPopulations by indexing the array using the FirstPopulatedBin and LastPopulatedBin
properties as boundaries Also shows code for determining coordinate of bin centers.
Const STARTROW = 5
Dim i As Integer
Dim BinPops
Dim FirstPopulatedBin, LastPopulatedBin As Integer
Dim OffsetAtLeftEdge As Double
Dim BinWidth As Double
BinPops = app.Math.F1.Out.Result.BinPopulations
FirstPopulatedBin = app.Math.F1.Out.Result.FirstPopulatedBin
LastPopulatedBin = app.Math.F1.Out.Result.LastPopulatedBin
OffsetAtLeftEdge = app.Math.F1.Out.Result.OffsetAtLeftEdge
BinWidth = app.Math.F1.Out.Result.BinWidth
For i = FirstPopulatedBin To LastPopulatedBin
Cells(i - FirstPopulatedBin + STARTROW + 1, 7) = i
Cells(i - FirstPopulatedBin + STARTROW + 1, 8) = OffsetAtLeftEdge +
(BinWidth / 2) + BinWidth * i
Cells(i - FirstPopulatedBin + STARTROW + 1, 9) = BinPops(i)
Next i
Bins
Number of bins in the histogram.
Applies to: Histogram
Dim Bins as Integer
Bins = app.Math.F1.Out.Result.Bins
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Part 4: Automation Result Interface Reference
BinWidth
Width of each bin in the histogram.
Applies to: Histogram
Dim BinWidth as double
BinWidth = app.Math.F1.Out.Result.BinWidth
BusName
Name of the bus, which can be configured via the user interface or by the automation property
app.LogicAnalyzer.Digital1.BusName.
Applies to: Digital
Dim BusName As String
BusName = app.LogicAnalyzer.Digital1.Out.Result.BusName
CellType
Datatype for the selected cell in a table. This is used in order to properly read out the CellValue.
Applies to: Table
Arguments
Row Long 0 = first row 0-based index of the row containing the cell. Use the Rows
property to determine the maximum number of rows.
Column Long 0 = first column 0-based index of the column containing the cell. Use the
Columns property to determine the maximum number of
columns.
Result Enum 0 = variant
2 = parameter result inter-
face
Result type. Other values exist but do not apply to the Table
interface.
Example
Dim CellType As Integer
CellType = app.SerialDecode.Decode1.Out.Result.CellType(1, 1)
The example above returns CellType for row 1, column 1.
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MAUI Oscilloscopes Remote Control and Automation Manual
CellValue
The value for the selected cell in a table. The method for reading back CellValue depends on the cell’s
CellType property. For cells where CellType Result = 0 (variant), then CellValue contains the cell’s value.
For CellType Result = 2, CellValue becomes a Param result interface with its own value property. See the
example for more information.
Applies to: Table
Arguments
Row Long 0 = first row 0-based index of the row containing the cell. Use the Rows
property to determine the maximum number of rows.
Column Long 0 = first column 0-based index of the column containing the cell. Use the
Columns property to determine the maximum number of
columns.
Example
When the CellType = 0, read out the value directly, as shown below. This call often returns "Idx", which is
the header for column 0:
Dim CellValue
CellValue = app.SerialDecode.Decode1.Out.Result.CellValue(0, 0)
The code below demonstrates how to read back the cell value when the CellType = 2:
Dim DecoderTableResult As Object
Set DecoderTableResult = app.SerialDecode.Decode1.Out.Result
Dim CellValueOb As Object
Set CellValueOb = DecoderTableResult.CellValue(1, 2)
CellValue = CellValueOb.Value
Oscilloscopes that have a serial decoder option include a script for outputting the table of decoded values.
This can be found on the oscilloscope in the D:\Applications folder.
Columns
Number of columns in the DataArray. Typically equal to 1000 for Persist waveforms. For Tables, the result
can vary depending on the application.
Applies to: Persist, Table
Persist Example
Dim Columns As Integer
Columns = app.SDA.Eye.Out.Result.Columns
Table Example
Dim Columns As Integer
Columns = app.SerialDecode.Decode1.Out.Result.Columns
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Part 4: Automation Result Interface Reference
DataArray
Variant array containing data for a trace. The implementation depends on the type of waveform.
Applies to: Digital, Persist, Waveform, XY
XY Interface
Arguments (optional)
arrayValuesScaled Boolean 1 (TRUE) = data is scaled
0 (FALSE) = data is raw
Determines whether returned values are scaled or raw.
Passing TRUE indicates scaled data; FALSE indicates raw
data. Default is TRUE. Scaled values are double precision;
raw values are 16-bit signed integers. See the properties
XVerticalPerStep, XVerticalResolution and XVerticalOffset
(and the corresponding Y coordinate) for more
information.
numSamples Long -1 = retrieve all data Number of samples to retrieved. Default is -1.
startIndex Long 0 = first sample Index of the first sample to be retrieved. Default is 0.
sparsingFactor Long 1 = no sparsing Determines the sparsing factor to use. Default is 1. A
sparsing factor of 5 means to retrieve every 5th point. Use
the math function Sparse to configure sparsing offset.
Example
Reads values to use for DataArray arguments from a spreadsheet, then loops through the retrieved array,
saving the data to the spreadsheet along with sample index and sample time.
Const ROWOFFSET = 10
Const COLOFFSET = 7
Dim HorizontalPerStep As Double
Dim HorizontalOffset As Double
Dim ScaleArray As Boolean
Dim nSamples As Long
Dim startIndex As Long
Dim sparseFactor As Long
Dim XYwform
ScaleArray = Cells(9, 5) nSamples = Cells(10, 5) startIndex = Cells(11, 5)
sparseFactor = Cells(12, 5)
XYwform = app.Math.XY.Out.Result.DataArray
HorizontalPerStep = app.Math.XY.Out.Result.HorizontalPerStep
HorizontalOffset = app.Math.XY.Out.Result.HorizontalOffset
For i = 0 To UBound(XYwform)
For j = 0 To 1 Cells(i + ROWOFFSET, COLOFFSET) = i
Cells(i + ROWOFFSET, COLOFFSET + 1) = HorizontalPerStep * i HorizontalOffset
Cells(i + ROWOFFSET, COLOFFSET + 2) = XYwform(i, 0)
Cells(i + ROWOFFSET, COLOFFSET + 3) = XYwform(i, 1)
Next j
Next i
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MAUI Oscilloscopes Remote Control and Automation Manual
Waveform Interface
Arguments (optional)
arrayValuesScaled Boolean 1 (TRUE) = data is scaled
0 (FALSE) = data is raw
Determines whether returned values are scaled or raw.
Passing TRUE indicates scaled data; FALSE indicates raw
data. Default is TRUE. Scaled values are double precision;
raw values are 16-bit signed integers. See the properties
VerticalPerStep, VerticalResolution and VerticalOffset for
more information.
numSamples Long -1 = retrieve all data Number of samples to retrieve. Default is -1.
startIndex Long 0 = first sample Index of the first sample to be retrieved. Default is 0.
sparsingFactor Long 1 = no sparsing Determines the sparsing factor to use. Default is 1. For
example, a sparsing factor of 5 means to retreive every 5th
point. Use the math function Sparse in order to configure
sparsing offset.
Example
Reads values to use for DataArray arguments from a spreadsheet, then loops through the retrieved array,
saving the data to the spreadsheet along with sample index and sample time.
Const ROWOFFSET = 10
Const COLOFFSET = 7
Dim HorizontalPerStep As Double
Dim HorizontalOffset As Double
Dim ScaleArray As Boolean
Dim nSamples As Long
Dim startIndex As Long
Dim sparseFactor As Long
Dim wform
ScaleArray = Cells(9, 5) nSamples = Cells(10, 5) startIndex = Cells(11, 5)
sparseFactor = Cells(12, 5)
wform = app.Acquisition.C1.Out.Result.DataArray
HorizontalPerStep = app.Acquisition.C1.Out.Result.HorizontalPerStep
HorizontalOffset = app.Acquisition.C1.Out.Result.HorizontalOffset
For i = 0 To UBound(wform)
Cells(i + ROWOFFSET, COLOFFSET) = i
Cells(i + ROWOFFSET, COLOFFSET +1) = HorizontalPerStep * i +HorizontalOffset
Cells(i + ROWOFFSET, COLOFFSET+2) = wform(i)
Next i
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Part 4: Automation Result Interface Reference
Persist Interface
Retrieves a 2D array containing hits in each cell of the rectangle selected via the input arguments.
Arguments (optional)
numColumns Long -1 = retrieve all columns Number of columns to retrieve. Default is -1.
numRows Long -1 = retrieve all rows Number of rows to retrieve. Default is -1.
startColumn Long 0 = first sample Index of the first column to be retrieved. Default is 0.
startRow Long 0 = first row Index of the first row to be retrieved. Default is 0.
Example
Reads values to use for DataArray arguments from a spreadsheet, then loops through the retrieved array,
saving the data to the spreadsheet.
Const ROWOFFSET = 10
Const COLOFFSET = 7
Dim numColumns As Long
Dim numRows As Long
Dim startColumn As Long
Dim startRow As Long
Dim wform
numColumns = Cells(9, 5) numRows = Cells(10, 5) startColumn = Cells(11, 5) startRow
= Cells(12, 5)
wform = app.SDA.Eye.Out.Result.DataArray(numColumns, numRows, startColumn,
startRow)
For i = 0 To numRows - 1
For j = 0 To numColumns - 1
Cells(i + ROWOFFSET, j + COLOFFSET) = wform(i, j)
Next j
Next i
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MAUI Oscilloscopes Remote Control and Automation Manual
Digital Interface
Retrieves a 2D array containing the state of each sample on each line. The value 1 is returned if he sample
was above the threshhold, 0 if below.
Arguments (optional)
numSamples Long -1 = retrieve all data Number of samples to retrieve. Default is -1.
numLines Long -1 = retrieve all digital lines Number of lines to retrieve. Default is -1.
startIndex Long 0 = first index Index of the first sample to be retrieved. Default is 0.
startLine Long 0 = first digital line Index of the first line to be retrieved. Default is 0. The user
selects which lines to enable; only data from enabled lines
are included in the DataArray
Example
Reads values to use for DataArray arguments from a spreadsheet, then loops through the retrieved array,
saving the data to the spreadsheet.
Const ROWOFFSET = 10
Const COLOFFSET = 7
Dim nSamples As Long
Dim nLines As Long
Dim startIndex As Long
Dim startLine As Long
Dim wform
nSamples = Cells(9, 5) nLines = Cells(10, 5) startIndex = Cells(11, 5) startLine =
Cells(12, 5)
wform = app.LogicAnalyzer.Digital1.Out.Result.DataArray(nSamples, nLines,
startIndex, startLine)
Saves the retrieved samples to a spreadsheet, with each digital line in a column:
For j = 0 To UBound(wform, 2)
For i = 0 To UBound(wform, 1)
Cells(i + ROWOFFSET, j + COLOFFSET) = wform(i, j)
Next j
Next i
ExtendedStatus
Reserved for future use.
Applies to: all Result Interfaces.
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Part 4: Automation Result Interface Reference
FirstEventTime
Absolute trigger time of the acquisition, or the time of the first trigger in an acquisition that utilizes multiple
sweeps. Examples of multi-sweep acquisitions are Sequence Mode and when a source channel is
configured for pre-processor averaging. Times are returned encoded as a currency value (VT_CY) within a
variant, which allows the use of the full 64-bit resolution of the timestamp value. Values are referenced to
1st Jan 2000, with 1ns resolution. Note that VT_CY values are stored as 64-bit (8 byte) two's complement
integers, scaled by 10,000 to give a fixed-point number with 15 digits to the left of the decimal point, and 4
digits after. See the example for details on decoding FirstEventTime as well as other properties that return
times, such as LastEventTime and UpdateTime.
Applies to: all Result Interfaces.
Dim FirstEventTime
Dim TimeString as String
FirstEventTime = app.Acquisition.C1.Out.Result.FirstEventTime
timeString = DecodeTimeProperty(FirstEventTime)
' Decode the FirstEventTime, LastEventTime and UpdateTime properties.
Function DecodeTimeProperty(ByVal EventTime) As String
Dim days, thedate, hours, thehour, minutes, theminute, seconds
Dim outstring As String
days = EventTime / (86400 * 100000#)
thedate = DateAdd("d", days, "1-Jan-00")
hours = (days - Int(days)) * 24
thehour = Int(hours)
minutes = (hours - thehour) * 60
theminute = Int(minutes)
seconds = (minutes - theminute) * 60
' Format output string:
DecodeTimeProperty = thedate & " " & thehour & ":" & theminute & ":" &seconds
End Function
FirstPopulatedBin
Index of the first populated bin. (The first bin of the histogram is bin 0).
Applies to: Histogram
Dim FirstPopulatedBin as Integer
FirstPopulatedBin = app.Math.F1.Out.Result.FirstPopulatedBin
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MAUI Oscilloscopes Remote Control and Automation Manual
HorizontalFrameStart
Coordinate of the left edge of the graticule containing the trace relative to the trigger time, which is at time
= 0.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim XFrameStart As Double
XFrameStart = app.Acquisition.C1.Out.Result.HorizontalFrameStart
HorizontalFrameStop
Coordinate of the right edge of the graticule containing the trace relative to the trigger time, which is at
time = 0.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim XFrameStop As Double
XFrameStop = app.Acquisition.C1.Out.Result.HorizontalFrameStop
HorizontalOffset
Time of the first sample. Note that the first sample is typically just off screen, to the left of the grid. Use
this value when calculating the time for each sample.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim HorizontalOffset As Double
HorizontalOffset = app.Acquisition.C1.Out.Result.HorizontalOffset
Dim HorizontalPerStep As Double
HorizontalPerStep = app.Acquisition.C1.Out.Result.HorizontalPerStep
Dim SampleTime as Double
Dim i as Long
For i = 0 to numPoints-1
SampleTime = HorizontalPerStep * i + HorizontalOffset
Next
For a more complete example, see the Waveform example in DataArray as well as the function
GetDataArray_Click.
HorizontalPerColumn
Difference in the horizontal coordinate of adjacent columns (typically in seconds). Use
HorizontalPerColumn to determine the timing information for each column of the DataArray.
Applies to: Persist
Dim HorizontalPerColumn As Double
HorizontalPerColumn = app.SDA.Eye.Out.Result.HorizontalPerColumn
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HorizontalPerStep
Time between samples, otherwise known as the sample interval. This is the inverse of the SampleRate.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim HorizontalPerStep As Double
HorizontalPerStep = app.Acquisition.C1.Out.Result.HorizontalPerStep
HorizontalResolution
Resolution of the readout of horizontal values. Not directly related to the sample period.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim HorizontalResolution As Double
HorizontalResolution = app.Acquisition.C1.Out.Result.HorizontalResolution
HorizontalUnits
Resolution of the readout of horizontal values. Not directly related to the sample period.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim HorizontalUnits As String
HorizontalUnits = app.Acquisition.C1.Out.Result.HorizontalUnits
HorizontalVarianceArray
Variant array with the variances from the nominal sample times. Used on WaveExpert oscilloscopes.
Applies to: Waveform, XY
Dim HorizontalUnits As Double
HorizontalUnits = app.Acquisition.C1.Out.Result.HorizontalUnits
HorizontalVariances
Number of elements in HorizontalVarianceArray. Used on WaveExpert oscilloscopes.
Applies to: Waveform, XY
Dim HorizontalVarianceArray
HorizontalVarianceArray =
app.Acquisition.C1.Out.Result.HorizontalVarianceArray
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IndexOfFirstSampleInFrame
Index of the first sample that appears in the graticule. This is typically index 1, since index 0 is off- grid to
the left when traces are zoomed.
Applies to: Waveform
Dim IndexOfFirstSampleInFrame as Long
IndexOfFirstSampleInFrame =
app.Acquisition.C1.Out.Result.IndexOfFirstSampleInFrame
LastEventTime
Time of the last contributing event in a set. Useful only when the result includes data produced by a
sequence acquisition, or a cumulative operation such as averaging. Times are returned encoded as a
currency value (VT_CY) within a variant; see description for FirstEventTime for decoding details.
Applies to: All Result interfaces.
Dim LastEventTime
Dim TimeString as String
LastEventTime = app.Acquisition.C1.Out.Result.FirstEventTime
TimeString = DecodeTimeProperty(LastEventTime)
See FirstEventTime for an example of decoding LastEventTime.
LastPopulatedBin
Index of the last populated bin. (The first bin of the histogram is bin 0).
Applies to: Histogram
Dim LastPopulatedBin as Long
LastPopulatedBin = app.Math.F1.Out.Result.LastPopulatedBin
Levels
Returns the value 2, corresponding to the number of levels possible.
Applies to: Digital
Dim Levels As Integer
Levels = app.LogicAnalyzer.Digital1.Out.Result.Levels
LineAliasName
Alias of the line name based on the input index. The alias for the line is displayed on the right side of the
grid, and have values of the form "D0", "D1", etc.
Applies to: Digital
Dim LineAliasName0
LineAliasName0 = app.LogicAnalyzer.Digital1.Out.Result.LineAliasName(0)
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LineName
Name of the line. This can be modified via the user interface or via the property
app.LogicAnalyzer.Digital1.LineNames.
Applies to: Digital
Dim LineName0
LineName0 = app.LogicAnalyzer.Digital1.Out.Result.LineName(0)
Lines
Number of lines in the digital bus.
Applies to: Digital
Dim Lines
Lines = app.LogicAnalyzer.Digital1.Out.Result.Lines
Max
Horizontal coordinate of the left edge of the last populated bin. It is equivalent to the hmax parameter.
Applies to: Histogram
Dim Max as double
Max = app.Math.F1.Out.Result.Max
MaxPopulation
Mode of the histogram (population of the bin with the most hits).
Applies to: Histogram
Dim MaxPopulation as Long
MaxPopulation = app.Math.F1.Out.Result.MaxPopulation
MaxPopulationBin
Index of the bin with the highest population. (The first bin of the histogram is bin 0).
Applies to: Histogram
Dim MaxPopulationBin as Integer
MaxPopulationBin = app.Math.F1.Out.Result.MaxPopulationBin
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MaxPopulationInRectangle
Population of the largest element in the selected rectangle.
Applies to: Persist
Arguments
numColumns Long -1 = use all columns Number of columns to use. Default is -1.
numRows Long -1 = use all rows Number of rows to use. Default is -1.
startColumn Long 0 = first sample Index of the first column. Default is 0.
startRow Long 0 = first row Index of the first row. Default is 0.
Example
Determining the maximum population in the rectangle.
Dim numColumns As Long
Dim numRows As Long
Dim startColumn As Long
Dim startRow As Long
Dim MaxPopulationInRectangle As Long
numColumns = Cells(9, 5)
numRows = Cells(10, 5)
startColumn = Cells(11, 5)
startRow = Cells(12, 5)
MaxPopulationInRectangle =
app.SDA.Eye.Out.Result.MaxPopulationInRectangle
(numColumns,numRows,startColumn,startRow)
Use no arguments to select the full rectangle:
MaxPopulationInRectangle = app.SDA.Eye.Out.Result.MaxPopulationInRectangle
Mean
Returns the mean value of the histogam. It is equivalent to the hmean parameter.
Applies to: Histogram
Dim hmean as double
hmean = app.Math.F1.Out.Result.Mean
Min
Horizontal coordinate of the left edge of the first populated bin. It is equivalent to the hmin parameter.
Applies to: Histogram
Dim hmin as double
hmin = app.Math.F1.Out.Result.Min
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NumFrameDimensions
Number of dimensions in the current result. For waveforms, this is typically = 2, (Voltage and time)
dimensions). For X-Y mode the result is 3.
Applies to: all Result Interfaces.
Dim NumFrameDimensions as Integer
NumFrameDimensions = app.Acquisition.C1.Out.Result.NumFrameDimensions
NumSamplesInFrame
Number of samples within the graticule.
Applies to: Waveform
Dim NumSamplesInFrame as Long
NumSamplesInFrame = app.Acquisition.C1.Out.Result.NumSamplesInFrame
OffsetAtLeftEdge
Horizontal coordinate of left edge of the first bin (either populated or unpopulated) displayed on the grid.
Use OffsetAtLeftEdge as an offset for calculating the position of each bin.
Applies to: Histogram
Read out BinPopulations by indexing the array using the FirstPopulatedBin and LastPopulatedBin
properties as boundaries Also shows code for determining coordinate of bin centers.
Const STARTROW = 5
Dim i As Integer
Dim BinPops
Dim FirstPopulatedBin, LastPopulatedBin As Integer
Dim OffsetAtLeftEdge As Double
Dim BinWidth As Double
BinPops = app.Math.F1.Out.Result.BinPopulations
FirstPopulatedBin = app.Math.F1.Out.Result.FirstPopulatedBin
LastPopulatedBin = app.Math.F1.Out.Result.LastPopulatedBin
OffsetAtLeftEdge = app.Math.F1.Out.Result.OffsetAtLeftEdge
BinWidth = app.Math.F1.Out.Result.BinWidth
For i = FirstPopulatedBin To LastPopulatedBin
Cells(i - FirstPopulatedBin + STARTROW + 1, 7) = i
' Calculate Bin Center:
Cells(i - FirstPopulatedBin + STARTROW + 1, 8) = OffsetAtLeftEdge +
(BinWidth / 2) + BinWidth * i
Cells(i - FirstPopulatedBin + STARTROW + 1, 9) = BinPops(i)
Next
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Peaks
Number of peaks in the histogram.
Applies to: Histogram
Dim NumPeaks as Integer
NumPeaks = app.Math.F1.Out.Result.Peaks
PeakInfo
Variant array returning information about the peak selected in the input argument. Sending 0 returns
information for the entire histogram; input values from 1 to Peaks+1 returns information about the
requested peak.
Applies to: Histogram
Arguments (optional)
peakIndex Long 0 = mean
1 = sigma
2 = unused
3 = unused
4 = FirstPopulatedBin
5 = LastPopulatedBin
6 = MaxPopulationBin
7 = MaxPopulation
8 = PopulationInside
Selects the peak of interest. 0 requests information about
the entire histogram; > 0 requests information about a
single peak. Default is 0.
Example
' Read out complete PeakInfo arrays for each peak.
Const STARTROW = 10
Const STARTCOL = 13
Dim PeakInfo
Dim i, j As Integer
Dim NumPeaks as Integer
NumPeaks = app.Math.F1.Out.Result.Peaks
For i = 0 To NumPeaks
' Index out a peak (index 0 is the entire histogram):
PeakInfo = app.Math.F1.Out.Result.PeakInfo(i)
Cells(STARTROW, STARTCOL + i) = i
' Loop through each element of the selected PeakInfo array (there are nine
elements):
For j = 0 To 8
Cells(STARTROW + j + 1, STARTCOL + i) = PeakInfo(j)
Next
Next
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PopulationInside
Population of the histogram for events contained within the number of bins configured.
Applies to: Histogram
Dim PopInside as Long
PopInside = app.Math.F1.Out.Result.PopulationInside
PopulationOfRectangle
Population of the selected rectangle.
Applies to: Persist
Arguments
numColumns Long -1 = retrieve all columns Number of columns to retrieve. Default is -1.
numRows Long -1 = retrieve all rows Number of rows to retrieve. Default is -1.
startColumn Long 0 = first sample Index of the first column to be retrieved. Default is 0.
startRow Long 0 = first row Index of the first row to be retrieved. Default is 0.
Example
Dim numColumns As Long
Dim numRows As Long
Dim startColumn As Long
Dim startRow As Long
Dim PopulationOfRectangle As Long
numColumns = Cells(9, 5)
numRows = Cells(10, 5)
startColumn = Cells(11, 5)
startRow = Cells(12, 5)
PopulationOfRectangle =
app.SDA.Eye.Out.Result.PopulationOfRectangle
(numColumns,numRows,startColumn,startRow)
PopulationOfRectangle = app.SDA.Eye.Out.Result.PopulationOfRectangle
(numColumns,numRows,startColumn,startRow)
PopulationOver
Population of the events greater than the last bin.
Applies to: Histogram
Dim PopOver as Long
PopOver = app.Math.F1.Out.Result.PopulationOver
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PopulationUnder
Population of the events less than the first bin.
Applies to: Histogram
Dim PopUnder as Long
PopUnder = app.Math.F1.Out.Result.PopulationUnder
RMS
RMS value of the histogram. Equivalent to the parameter hrms.
Applies to: Histogram
Dim hRMS as Double
hRMS = app.Math.F1.Out.Result.RMS
Rows
Number of rows in the DataArray (Persist) or in the table. Typically equal to 256 for Persist waveforms. For
Tables, the result can vary depending on the application.
Applies to: Persist, Table
Dim Rows As Integer
Rows = app.SDA.Eye.Out.Result.Rows
Samples
Number of samples in the waveform. For the Waveform and XY interface, this is typically the number of
samples configured for the acquisition (e.g. 500) plus 2. The additional two points are off-grid, one on each
side. For the Digital interface, this is the number of samples in each digital line + 1.
Applies to: Digital, Waveform, XY
Dim Samples as Long
Samples = app.Acquisition.C1.Out.Result.Samples
Sdev
Standard deviation of the histogram. Equivalent to the parameter hsdev.
Applies to: Histogram
Dim hsdev as Double
hsdev = app.Math.F1.Out.Result.Sdev
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Part 4: Automation Result Interface Reference
Status
Result status. Status is returned as a decimal value, but should be treated like a register with the following
bit values. See the example for decoding the Status result.
64-bit Hex VT_Decimal Status Description
Value shown in
XStreamBrowser
Value returned
from Status
property
0x1 0.0001 Invalid result Indicate that this Result cannot be used for any
calculation.
0x2 0.0002 Data overflow Result contains Overflow data or is calculated from a
Result containing Overflows.
0x4 0.0004 Data underflow Result contains Underflow data or is calculated from a
Result containing Underflows.
0x8 0.0008 Some values are
undefined
Result contains some values or data that are
undefined.
0x10 0.0016 Less than Actual value is likely to be less than the calculated
value. Mostly used for parameter measurements.
0x20 0.0032 Greater than Actual value is likely to be greater than the calculated
value. Mostly used for parameter measurements.
0x40 0.0064 Not a pulse Analyzed signal is not recognized as a pulse; mostly
used for pulse parameter measurements.
0x80 0.0128 Not cyclic Contains some values measured on non-cyclic signal.
0x100 0.0256 Data averaged Calculated value is the result of an average of multiple
measurements.
0x200 0.0512 Unlocked PLL Unlocked PLL
0x400 0.1024 Other error Indicates some other error condition, usually
accompanied by a processor-specific status
description.
0x800 0.2048 Other warning Indicates some other warning condition, usually
accompanied by a processor-specific status
description.
0x1000 0.4096 Other info Indicates some other informative condition, usually
accompanied by a processor-specific status
description.
0x2000 0.8192 Cumulative result Cumulative processing somewhere in the chain
0x4000 to 0x200000 1.6384 to
209.7152
Reserved
0x400000 419.4304 Not an NRZ Eye Not an NRZ Eye
0x800000 838.8608 Not an RZ Eye Not an RZ Eye
0x1000000 to
0x80000000
1677.7216 to
214748.3648
Reserved
0x100000000 429496.7296 Inputs incompatible Some incompatibility exists between inputs (e.g. units,
frame, sample rate)
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MAUI Oscilloscopes Remote Control and Automation Manual
64-bit Hex VT_Decimal Status Description
0x200000000 858993.4592 Algorithm limits
reached
Algorithm couldn't converge or some other algorithmic
limitation reached.
0x400000000 1717986.918 Bad settings Combination of settings isn't correct.
0x800000000 3435973.837 Too little data Not enough data to accurately perform calculation.
0x1000000000 6871947.674 Too much data Too much data to perform calculation.
0x2000000000 13743895.35 Requires uniform
horizontal interval
Uniform horizontal interval required.
0x4000000000 27487790.69 Bad units Incorrect or invalid units
0x8000000000 54975581.39 Data range too low Range of data values is too close to the resolution
(e.g. bad signal to noise ratio).
0x10000000000 109951162.8 Data undersampled Sample rate too low
0x20000000000 219902325.6 Poor statistics Too few samples (e.g., to populate a data histogram to
have enough statistics).
0x40000000000 439804651.1 Slow transition time Transition time too slow (e.g., JTA time measurement
accuracy for clock that requires fast edges).
0x80000000000 879609302.2 Data resampled Data is resampled
0x100000000000 1759218604 Data interpolated Data is interpolated (e.g., interpolating missing points
in RIS).
0x200000000000 3518437209 Measurement scale
imprecise
If all the data falls in the same histogram bin, one line
for trend, one pixel for XY, etc.
0x400000000000 7036874418 No data available Data not available (e.g., processing inputs
disconnected or clear sweeps on cumulative
processing).
0x800000000000 14073748836 Some accumulated
results invalid
One or more results or values within the accumulated
result were invalid and were skipped.
0x1000000000000 28147497671 Insufficient Memory Memory limitations reached, attempted allocations
failed.
0x2000000000000 56294995342 Channel not active Source channel inactive.
0x4000000000000 1.1259E+11 Use status description (custom string)
0x8000000000000 to
0x8000000000000000
Reserved
StatusDescription
Description for each status code. See the above table.
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Sweeps
Number of sweeps used for results that are based on multiple sweeps, such as averages, histograms, eye
diagrams, etc.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim Sweeps as Long
Sweeps = app.Acquisition.C1.Out.Result.Sweeps
Top
Horizontal coordinate of the rightmost of the two most populated histogram peaks. It is equivalent to the
paramater htop.
Applies to: Histogram
Dim htop as Double
htop = app.Math.F1.Out.Result.Top
UniformInterval
Returns if the samples are evenly spaced in time. Currently always true.
Applies to: Digital
UpdateTime
Indicates the time that particular result was most recently updated. Often, this property will show the
same value as LastEventTime, but for traces such as memories (M1, M2, etc) this will be the time that the
waveform was stored to the memory trace. Times are returned encoded as a currency value (VT_CY)
within a variant; see description for FirstEventTime for decoding details.
Applies to: all Result Interfaces.
Dim UpdateTime
Dim TimeString as String
UpdateTime = app.Memory.M1.Out.Result.UpdateTime
TimeString = DecodeTimeProperty(UpdateTime)
See FirstEventTime for the code for the function DecodeTimeProperty, which is the example of decoding
UpdateTime.
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Value
Value of a parameter or of a statistic in the measurement system. When the scope has no result, it will
show "---" in the measure table. When this is displayed, the Value property is not accessible. Error handling
should be employed to catch errors that may occur. Use the On Error Resume Next statement to handle
situations where a measurement is not available, such as attempting to read back the frequency of a DC
level, or trying to read the Sdev statistic when there is only 1 measurement.
Applies to: Param
' Readout all elements of the measurement parameter for P1
On Error Resume Next
Dim Value, Mean, Min, Max, Sdev, Num As Double
Value = app.measure.p1.out.Result.Value
Mean = app.measure.p1.Mean.Result.Value
Min = app.measure.p1.Min.Result.Value
Max = app.measure.p1.Max.Result.Value
Sdev = app.measure.p1.Sdev.Result.Value
Num = app.measure.p1.Num.Result.Value
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ValueArray
Applies to: Param
Description: Retrieves a 1D array of values, typically used to return measurement results for multi-value
parameters such as Period, Frequency, TIE@level, etc. ValueArray can also return the start time, stop
time, and status (edge polarity) of each measurement taken in the sweep.
Arguments
numSamples Long -1 = retrieve all data Number of samples to retrieved. Default is -1.
startIndex Long 0 = first sample Index of the first sample to be retrieved. Default is 0.
valueType Integer
(enum)
1 = parameter value
2 = measurement start time
4 = measurement start time
8 = status value
Determines the value to read back. Default is 1. Use Status
(8) to determine if edge measurements are of positive or
negative polarity.
Example
Read out all properties of the measurement parameter for P1. Use the On Error Resume Next statement
to handle situations where no measurements were taken. The scope will show "---" when there is no result
to read back.
Const ROWOFFSET = 16
Const COLOFFSET = 2
Dim numValues As Long
Dim startIndex As Long
Dim valueType As Integer
Dim valArray
numValues = Cells(9, 5) startIndex = Cells(10, 5)
valArray = app.measure.p1.out.Result.ValueArray(numSamples,startIndex,1)
startTimes = app.measure.p1.out.Result.ValueArray(numSamples,startIndex,2)
stopTimes = app.measure.p1.out.Result.ValueArray(numSamples,startIndex,4)
statusVals = app.measure.p1.out.Result.ValueArray(numSamples,startIndex,8)
Dim Value, Mean, Min, Max, Sdev, Num As Double
For i = 0 To UBound(valArray)
Cells(i + ROWOFFSET, COLOFFSET) = i
Cells(i + ROWOFFSET, COLOFFSET + 1) = valArray(i)
Cells(i + ROWOFFSET, COLOFFSET + 2) = startTimes(i)
Cells(i + ROWOFFSET, COLOFFSET + 3) = stopTimes(i)
Cells(i + ROWOFFSET, COLOFFSET + 4) = statusVals(i)
Next i
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MAUI Oscilloscopes Remote Control and Automation Manual
VerticalFrameStart
Vertical coordinate of the bottom edge of the graticule containing the trace.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim YFrameStart As Double
YFrameStart = app.Acquisition.C1.Out.Result.VerticalFrameStart
VerticalFrameStop
Vertical coordinate of the top edge of the graticule containing the trace.
Applies to: Digital, Histogram, Persist, Waveform, XY
Dim YFrameStop As Double
YFrameStop = app.Acquisition.C1.Out.Result.VerticalFrameStop
VerticalMaxPossible
Returns the maximum voltage that can be returned.
Applies to: Waveform
Dim VerticalMaxPossible As Double
VerticalMaxPossible = app.Acquisition.C1.Out.Result.VerticalMaxPossible
VerticalMinPossible
Returns the minimum voltage that can be returned.
Applies to: Waveform
Dim VerticalMinPossible As Double
VerticalMinPossible = app.Acquisition.C1.Out.Result.VerticalMinPossible
VerticalOffset
Potential difference between ground and the center of the screen. With VerticalOffset = +50 mV, the
center of the screen represents -50 mV: with an offset of -21mV, the center represents +21 mV. (i.e.,
centerline voltage + VerticalOffset = 0)
Applies to: Persist, Waveform
Dim VerticalOffset As Double
VerticalOffset = app.Acquisition.C1.Out.Result.VerticalOffset
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VerticalPerRow
Returns the increment of the vertical coordinate between rows (typically in volts). Use VerticalPerRow to
determine the voltage information for each row of the DataArray.
Applies to: Persist
Dim VerticalPerRow As Double
VerticalPerRow = app.SDA.Eye.Out.Result.VerticalPerRow
VerticalPerStep
Smallest step size in the numerical values that can be read out from the DataArray, which utilizes 16-bit
signed integer values. Note that the vertical range is almost exactly 65536 * VerticalPerStep. (See
VerticalMaxPossible and VerticalMinPossible.)
Applies to: Waveform
Dim VerticalPerStep as Double
VerticalPerStep = app.Acquisition.C1.Out.Result.VerticalPerStep
VerticalResolution
Vertical resolution of the Y coordinate, which is the actual smallest difference that can be practically
resolved. Using averaging can improve the resolution by the square root of the number of sweeps in the
average. For example, if 16 averages are set via pre-processor averaging or by using the Average math
function, the resolution is improved by a factor of 4. For 100 sweeps it improves by a factor of 10.
Applies to: Param, Waveform
Dim VerticalResolution as Double
VerticalResolution = app.Acquisition.C1.Out.Result.VerticalResolution
VerticalUnits
Units used for the vertical axis. Typically V for volts, but other units are possible, such as "A" for amps when
using a current probe. When selecting to change units when using the Rescale math function, a variety of
other chooses for units are available.
Applies to: Histogram, Param, Persist, Waveform
Dim VerticalUnits as String
VerticalUnits = app.Acquisition.C1.Out.Result.VerticalUnits
XFrameStart
Coordinate of the left edge of the XY graticule.
Applies to: XY
Dim XFrameStart As Double
XFrameStart = app.Math.XY.Out.Result.XFrameStart
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XFrameStop
Coordinate of the right edge of the XY graticule.
Applies to: XY
Dim XFrameStop As Double
XFrameStop = app.Math.XY.Out.Result.XFrameStop
XMaxPossible
Maximum possible value of the X coordinate
Applies to: XY
Dim XMaxPossible As Double
XMaxPossible = app.Math.XY.Out.Result.XMaxPossible
XMinPossible
Minimum possible value of the X coordinate
Applies to: XY
Dim XMinPossible As Double
XMinPossible = app.Math.XY.Out.Result.XMinPossible
XOffset
Potential difference between ground and the horizontal center of the XY grid. For example, with
VerticalOffset of the X coordinate’s source trace = +50 mV, the center of the screen represents -50 mV:
with an offset of -21mV, the center represents +21 mV. (I.e. centerline voltage + VerticalOffset = 0)
Applies to: XY
Dim XOffset As Double
XOffset = app.Math.XY.Out.Result.XOffset
XPerStep
Smallest step size in the numerical values that can be read out from the DataArray utilzing 16 bit signed
integer values. Note that the X range is just about 65536 * XPerStep. (See XMaxPossible and
XMinPossible.)
Applies to: XY
Dim XPerStep As Double
XPerStep = app.Math.XY.Out.Result.XPerStep
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XResolution
Vertical resolution of the X coordinate, which is the actual smallest difference that can be practically
resolved. Using averaging can improve the resolution by the square root of the number of sweeps in the
average. For example, if 16 averages are set via pre-processor averaging or by using the Average math
function, the resolution is improved by a factor of 4. For 100 sweeps it improves by a factor of 10.
Applies to: XY
Dim XResolution As Double
XResolution = app.Math.XY.Out.Result.XResolution
XUnits
Units of the X coordinate. Typically V for Volts, unless a current probe is in use or if the Rescale function is
being used to change the trace’s units.
Applies to: XY
Dim XUnits As String
XUnits = app.Math.XY.Out.Result.XUnits
YFrameStart
Coordinate of the bottom edge of the XY graticule.
Applies to: XY
Dim YFrameStart As Double
YFrameStart = app.Math.XY.Out.Result.YFrameStart
YFrameStop
Coordinate of the top edge of the XY graticule.
Applies to: XY
Dim YFrameStart As Double
YFrameStart = app.Math.XY.Out.Result.YFrameStart
YMaxPossible
Minimum possible value of the Y coordinate.
Applies to: XY
Dim YMaxPossible As Double
YMaxPossible = app.Math.XY.Out.Result.YMaxPossible
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MAUI Oscilloscopes Remote Control and Automation Manual
YMinPossible
Minimum possible value of the Y coordinate.
Applies to: XY
Dim YMinPossible As Double
YMinPossible = app.Math.XY.Out.Result.YMinPossible
YOffset
Potential difference between ground and the vertical center of the XY grid. For example, with
VerticalOffset of the Y coordinate’s source trace = +50 mV, the center of the screen represents -50 mV:
with an offset of -21mV, the center represents +21 mV. (centerline voltage + VerticalOffset = 0)
Applies to: XY
Dim YOffset As Double
YOffset = app.Math.XY.Out.Result.YOffset
YPerStep
Smallest step size in the numerical values that can be read out from the DataArray utilzing 16 bit signed
integer values. Note that the Y range is just about 65536 * YPerStep. (See YMaxPossible and
YMinPossible.)
Applies to: XY
Dim YPerStep As Double
YPerStep = app.Math.XY.Out.Result.YPerStep
YResolution
Vertical resolution of the Y coordinate, which is the actual smallest difference that can be practically
resolved. Using averaging can improve the resolution by the square root of the number of sweeps in the
average. If 16 sweeps are averaged via pre-processor averaging or by using the Average math function,
the resolution is improved by a factor of 4; over 100 sweeps, it improves by a factor of 10.
Applies to: XY
Dim YResolution As Double
YResolution = app.Math.XY.Out.Result.YResolution
YUnits
Units of the Y coordinate. Typically V for Volts, unless a current probe is in use or if the Rescale function is
being used to change the trace’s units.
Applies to: XY
Dim YUnits As String
YUnits = app.Math.XY.Out.Result.YUnits
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Part 5: IEEE 488.2 Programming Reference
Part 5: IEEE 488.2 Programming Reference
Teledyne LeCroy implemented a subset of the IEEE 488.2 General Purpose Interface Bus (GPIB) for
remote control of oscilloscopes from a PC or other controller device. The original implementation utilized a
GPIB interface, and subsequently drivers and utilities were added for sending encapsulated GPIB
commands over ENET and other interfaces.
The examples in this reference are intended to show IEEE 488.2 command syntax, rather than to detail
how to program a GPIB interface. However, where examples are given, they assume the use of a National
Instruments GPIB card and some form of the BASIC programming language:
lVariables ending with % are integers.
lVariables ending with $ are strings.
lWhere INCLUDES are mentioned, this points to the need to couple the program to the GPIB by
including some drivers.
Note: It is not necessary to use a GPIB interface in order to use the legacy 488.2 commands with
Teledyne LeCroy oscilloscopes. If you are using the GPIB interface, any programming language
can be used provided it can be linked to GPIB.
GPIB Overview 5-2
Interface Definitions 5-2
IEEE 488.1 Standard Messages 5-3
Program Message Format 5-4
Data Types 5-7
Response Messages 5-9
I/O Buffers 5-10
Making Service Requests 5-11
Taking Instrument Polls 5-12
Timing and Synchronization 5-16
Waveform Transfer 5-19
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MAUI Oscilloscopes Remote Control and Automation Manual
GPIB Overview
The IEEE 488.2 General Purpose Interface Bus (GPIB) is similar to a standard computer bus. While the
computer interconnects circuit cards by means of a backplane bus, the GPIB interconnects independent
devices (oscilloscopes and computers, for example) by means of a cable bus.
The GPIB carries both interface and program messages.
lInterface messages manage the bus itself. They perform functions such as the initialization,
addressing and unaddressing of devices, and the setting of remote and local modes.
lProgram messages (often called device-dependent messages) contain programming instructions,
status information, and data—such as oscilloscope set up instructions and measurement data.
Devices connected by GPIB can be listeners, talkers, or controllers. A talker sends program messages to
one or more listeners, while a controller manages the flow of information on the bus by sending interface
messages to the devices.
When GPIB is implemented with Teledyne LeCroy oscilloscopes, the oscilloscope can be a talker or
listener, but not a controller. The controller functions are handled by another instrument, usually a PC. The
host computer must be able to play all three roles.
The details of how the controller configures the GPIB for different functions is specific to each GPIB
interface and can be found in the GPIB interface manufacturer's manual.
Note: VISA and ActiveDSO drivers perform all GPIB interface functionality, so you do not need to
learn the lower-level details of the GPIB bus to use the IEEE 488.2 commands.
Interface Definitions
Teledyne LeCroy oscilloscope interface capabilities include the following IEEE 488.1 definitions:
lAH1 - Complete Acceptor Handshake
lSH1 - Complete Source Handshake
lL4 - Partial Listener Function
lT5 - Complete Talker Function
lSR1 - Complete Service Request Function
lRL1 - Complete Remote/Local Function
lDC1 - Complete Device Clear Function
lDT1 - Complete Device Trigger
lPP1 - Parallel Polling: remote configurable
lC0 - No Controller Functions
lE2 - Tri-state Drivers
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Part 5: IEEE 488.2 Programming Reference
IEEE 488.1 Standard Messages
The IEEE 488.1 standard (of which IEEE 488.2 can be considered an extension) specifies not only the
mechanical and electrical aspects of the GPIB, but also the low-level transfer protocol. For instance, it
defines how a controller addresses devices, turns them into talkers or listeners, resets them, or puts them
in the remote state. Such interface messages are executed through the interface management lines of
the GPIB, usually with ATN true. All these messages except GET are executed immediately upon receipt.
The Command Reference in this manual does not contain a command for clearing the input or output
buffers or for setting the oscilloscope to the remote state because such commands are already specified
as IEEE 488.1 standard messages. Refer to the GPIB interface manual of the host controller as well
regarding its support programs, which should contain special calls for the execution of these messages.
Note: In addition to the IEEE 488.1 interface message standards, the IEEE 488.2 standard specifies
certain standardized program messages (or command headers). They are identified in the
Command Reference section with a leading asterisk *.
Remote Enable, RWLS
Teledyne LeCroy oscilloscopes do not lock out any local controls when placed in the remote state, or in
RWLS. They always accept remote and local control inputs (unless the remote control capability is turned
off).
Device Clear, DCL
In response to a universal Device CLear (DCL) or a Selected Device Clear message (SDC), the oscilloscope
clears the input or output buffers, cancels the interpretation of the current command (if any) and clears
pending commands. However, status registers and status-enable registers are not cleared. Although DCL
will have an immediate effect, it can take several seconds to execute if the oscilloscope is busy.
Group Execute Trigger
The Group Execute Trigger message (GET) causes the oscilloscope to arm the trigger system, and is
functionally identical to the *TRG command.
Interface Clear, IFC
The Interface Clear message (IFC) initializes the GPIB but has no effect on the operation of the
oscilloscope.
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MAUI Oscilloscopes Remote Control and Automation Manual
Program Message Format
GPIB program messages are composed of commands and/or queries separated by semicolons and
ending with a terminator:
<command/query>; . . . ;<command/query> <terminator>
Note: A terminator is required but is not shown in examples because usually it is automatically
added by the interface driver routine writing to GPIB.
The general form of a command or a query consists of an optional header path, followed by a command
header, followed by one or several parameters:
[header path:]<header>[?] [<parameter>,...,<parameter>]
The following rules apply:
lThere is a space between the header and the first parameter.
lCommas separate parameters.
lThe question mark [?] is optional and turns the command into a query.
lYou can use uppercase or lowercase characters, or both, in program messages; the oscilloscope
does not distinguish between them. An exception is the MESSAGE command, which can faithfully
transmit strings containing both lowercase and uppercase letters.
Commands and queries are executed in the order in which they are received through remote
transmission.
Commands and Queries
Program messages are made up of one or more commands or queries:
oCommands direct the oscilloscope to change its state, for example, its timebase or vertical
sensitivity.
oQueries ask the oscilloscope to return data, such as a measurement, register value or state
information. They are recognized by ?following the header.
Usually, you will use the same characters for a command and a query, the query being identified by "?" as
the final character. The portion of the header preceding the question mark is repeated as part of the
response message.
For example, to change the timebase to 2ms/div, send this command to the oscilloscope:
TIME_DIV 2E-3
To ask the oscilloscope about its timebase setting, send this query:
TIME_DIV?
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Part 5: IEEE 488.2 Programming Reference
You will receive a response like:
TIME_DIV 2E-3 S
Tip: Querying can be a useful way of generating a command that is known to be correct, and the
response copied straight into your program. The repeated header text can be suppressed with the
command COMM_HEADER.
Header path
Certain commands or queries apply to a subsection of the oscilloscope. A single input channel or traces on
the display are examples of such commands. These commands must have their headers prefixed with a
path name indicating the channel or trace recipient of the command.
The header path normally consists of a two-letter path name followed by a colon :immediately preceding
the command header.
EXAMPLE: C1:OFST -300 MV is a command to set the offset of Channel 1 to -300 mV.
The target waveform trace is specified using the following header path names:
Header Path Name Waveform Trace
C1 to CxChannels
M1 to MxMemory traces
F1 to FxMath function traces
TA, TB, TC, TD Equivalent to F1 through F4, for backward compatibility with legacy instruments
EX, EX10, EX5 External trigger
LINE LINE source for trigger
Note: When older trace names are used, such as TC, the oscilloscope response shows the new
label equivalent. So, a TC header path query would return as an F3 header path response.
Header paths need only need be specified once until the path changes. Subsequent commands without
header paths are assumed to refer to the most recently defined path.
Although optional, it's recommended to always use header paths to minimize the risk of error if the
command order changes.
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MAUI Oscilloscopes Remote Control and Automation Manual
Header
The header is the mnemonic form of the operation to be performed by the oscilloscope, what we usually
think of as the command or query. Most command and query headers have a long form, which allows
them to be read more easily by people, and a short form for better transfer and decoding speed. The two
are fully equivalent and can be used interchangeably.
EXAMPLE:TRIG_MODE AUTO and TRMD AUTO are two separate but equivalent commands for
switching to the automatic trigger mode.
Some command or query mnemonics are imposed by the IEEE 488.2 standard. They are standardized so
different oscilloscopes present the same programming interface for similar functions. All these
mnemonics begin with an asterisk *.
Parameters
Whenever a command or query uses additional parameter values, the values are expressed as ASCII
characters.
ASCII data can take the form of character, numeric, string, or block data. See Data Types.
There is a single exception: the transfer of waveforms with the WAVEFORM command/query, where the
waveform can be expressed as a sequence of binary data values. Refer to the Waveform Template topic
for details.
Terminator
The oscilloscope does not decode an incoming program message before receiving its terminator unless
the message is longer than the 256 byte input buffer (at which point the oscilloscope starts analyzing the
message once the buffer is full).
Most interface driver software will send the program message with the required terminators. You do not
have to include them in your programs. See I/O Buffers for more information.
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Part 5: IEEE 488.2 Programming Reference
Data Types
ASCII data can have the form of character,numeric,string, or block data.
Character Data
These are simple words or abbreviations indicating a specific action.
F3:TRA ON
The data value ON commands the trace F3 to be turned on (the data value OFF has the opposite effect).
This example can become more complex. In some commands, where you can specify as many as a
dozen different parameters, or where not all the parameters are applicable at the same time, the format
requires pairs of data values. The first value names the parameter to be modified, while the second gives
its value. Only the parameter pairs to be changed must be specified.
HARDCOPY_SETUP DEV,EPSON,PORT,GPIB
Here, two pairs of parameters are used. The first specifies the device as an EPSON (or compatible) printer,
while the second indicates the GPIB port.
The command HARDCOPY_SETUP allows many more parameters other than the ones specified here.
Either they are not relevant for printers or they are left unchanged.
Numeric Data
The numeric data type is used to enter quantitative information. Numbers can be entered as integers,
fractions, or exponents:
lF1:VPOS -5 - Move the display of Trace A downward by five divisions.
lC2:OFST 3.56 - Set the DC offset of Channel 2 to 3.56 V.
lTDIV 5.0E-6 - Adjust the timebase to 5 µsec/div.
There are many ways to set the oscilloscope's timebase to 5 µsec/div, such as:
lTDIV 5E-6 - Exponential notation, without any suffix.
lTDIV 5 US - with multiplier U (1E-6) and (optional) unit S for seconds
String Data
This data type enables you to transfer a (long) string of characters as a single parameter. Simply enclose
any sequence of ASCII characters between single or double quotation marks:
MESSAGE 'Connect probe to point J3'
Note: The oscilloscope displays this message in the message bar at the bottom of the touch
screen display.
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MAUI Oscilloscopes Remote Control and Automation Manual
Block Data
These are binary data values coded in hexadecimal ASCII: four-bit nibbles translated into the digits 0
through 9 or A through F, and transmitted as ASCII characters. They are used only for the transfer of
waveforms from the oscilloscope to the controller (WAVEFORM) and for instrument panel setups (PANEL_
SETUP).
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Part 5: IEEE 488.2 Programming Reference
Response Messages
The oscilloscope sends a response message to the controller in answer to a query. The format of such
messages is the same as that of program messages: individual responses in the format of commands,
separated by semicolons ; and ending in terminators (not shown in these examples). These messages can
be sent back to the oscilloscope in the form in which they were received as valid commands.
For example, when the controller sends the program message:
TIME_DIV?;TRIG_MODE NORM;C1:COUPLING?
The oscilloscope might respond with:
TIME_DIV 50 NS;C1:COUPLING D50
The response message refers only to the queries: the TRIG_MODE command is left out. If this response is
sent back to the oscilloscope, it is a valid program message for setting its timebase to 50ns/div and the
input coupling of Channel 1 to 50Ω.
This table outlines syntactical variations between program messages and response messages. The
oscilloscope keeps to stricter rules for response messages than for acceptance of program messages.
Program Response
Uppercase or lowercase characters Always uppercase characters
May contain extraneous spaces or tabs (white space) No extraneous spaces or tabs (white space)
May contain a mixture of short and long command or query
headers
Use short headers by default
Can use COMM_HEADER command to force the
oscilloscope to use long headers, or none at all
Tip: Many drivers set up COMM_HEADER in an Initialization function. COMM_HEADER need only
be set up once, typically in the configuration stage of your application. There may be
programmatic advantages to removing the headers from responses, especially if the return data
will be read into another program.
Waveforms you obtain from the oscilloscope using the query WAVEFORM? are a special kind of response
message. Control their exact format by using the COMM_FORMAT and COMM_ORDER commands.
Whenever you expect a response from the oscilloscope, you must have the control program instruct the
bus to read from the oscilloscope. If the controller sends another program message without reading the
response to the previous one, the response message in the output buffer of the oscilloscope is discarded.
Depending on the state of the oscilloscope and the computation to be done, several seconds may pass
before a response to a query is received.
Note: Remote command interpretation does not have priority over other oscilloscope activities.
Set the controller I/O timeout conditions to three or more seconds to give the oscilloscope time to
respond. An incorrect query will not get a response, but a beep will sound if the Remote Control
Assistant is enabled.
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MAUI Oscilloscopes Remote Control and Automation Manual
I/O Buffers
The oscilloscope has 256-byte input and output buffers. An incoming program message is not decoded
before a message terminator has been received.
Valid GPIB terminators are:
l<NL>- New line character, meaning, the ASCII new-line character (decimal value is 10).
l<NL><EOI> - New Line character with a simultaneous <EOI> signal.
l<EOI><EOI> - Signal together with the last character of the program message.
Note: Terminators are often not shown in examples because they are handled by the driver
software, although they are required. The <NL> <EOI> terminator is always used in response
messages sent by the oscilloscope to the controller.
However, if the input buffer becomes full (because the program message is longer than the buffer), the
oscilloscope starts analyzing the message. In this case, data transmission is temporarily halted, and the
controller may generate a timeout if the limit was set too low.
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Part 5: IEEE 488.2 Programming Reference
Making Service Requests
When the oscilloscope is used in a remote application, events often occur asynchronously; meaning, at
unpredictable times for the host computer. The most common example of this is a trigger wait after the
oscilloscope is armed. In such a case, the controller must wait until the acquisition is finished before it can
read the acquired waveform.
The simplest way of checking if a certain event has occurred is by either continuously or periodically
reading the status bit associated with it until the required transition is detected.
A more efficient way of detecting events occurring in the oscilloscope is to use Service Request (SRQ).
This GPIB interrupt line can be used to interrupt program execution in the controller. The controller can
then execute other programs while waiting for the oscilloscope.
The SRQ bit is latched until the controller reads the Status Byte Register (STB). The action of reading the
STB with the command *STB? clears the register contents except the MAV bit (bit 4) until a new event
occurs. Service requesting can be disabled by clearing the SRE register with the *SRE 0 command.
Unfortunately, not all interface manufacturers support the programming of interrupt service routines. In
particular, National Instruments supports only the SRQ bit within the ISTA% status word. This requires you
to continuously or periodically check this word, either explicitly or with the function call IBWAIT.
Enabling SRQ
In the default state, SRQ is disabled. To enable SRQ, set the Service Request Enable register with the *SRE
command, specifying which event should generate an SRQ.
The oscilloscope then interrupts the controller when the selected event(s) occur by asserting the SRQ
interface line. If several devices are connected to the GPIB, you may be required to identify which
oscilloscope caused the interrupt by serial polling the various devices.
INR and INB
This event is tracked by the INR register, which is reflected in the SRE register as the INB summary bit in
position 0. Since bit position 0 has the value 1, the command *SRE 1 enables the generation of SRQ
whenever the INB summary bit is set.
In addition, the events of the INR register that may be summarized in the INB bit must be specified. The
event "new signal acquired" corresponds to INE bit 0 (value 1) while the event "return-to-local" is assigned
to INE bit 2 (value 4). The total sum is 1+4=5. So, the command INE 5 is needed:
CMD$ = "INE 5 ; *SRE 1" : CALL IBWRT (SCOPE%, CMD$)
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MAUI Oscilloscopes Remote Control and Automation Manual
Taking Instrument Polls
You can regularly monitor state transitions within the oscilloscope by polling selected internal status
registers.
Four basic polling methods are used to detect the occurrence of a given event: continuous,serial,
parallel, and *IST. The simplest of these is continuous polling while the others are appropriate only when
interrupt-service routines (servicing the SRQ line) are supported, or multiple devices on GPIB require
constant monitoring.
The following examples accomplish the same goal (determining whether a new acquisition has taken
place) in order to emphasize the differences between the polling methods. The examples use board-level
GPIB function calls. It is assumed that the controller (board) and the oscilloscope (device) are located at
addresses 0 and 4, respectively.
The listener and talker addresses for the controller and the oscilloscope are:
Logic Device Listener Address Talker Address
External Controller 32 (ASCII<space>) 64 (ASCII @)
Oscilloscope 32 + 4 = 36 (ASCII $) 64 + 4 = 68 (ASCII D)
Continuous Polling
A status register is continuously monitored until a transition is observed. This is the most straightforward
method for detecting state changes, but may not be practical in certain situations, especially with multiple
device configurations.
In the following example, the event "new signal acquired" is observed by continuously polling the Internal
State Change Register (INR) until the corresponding bit (in this case bit 0, or value 1) is non-zero, indicating
a new waveform has been acquired. Reading INR clears this at the same time, so there is no need for an
additional clearing action after a non-zero value is detected. The CHDR OFF command instructs the
oscilloscope to omit any command headers when responding to a query, simplifying the decoding of the
response. The oscilloscope then sends "1" instead of "INR 1" as follows:
Example: Continuous Polling
CMD$ = "CHDR OFF"
CALL IBWRT (SCOPE%, CMD$)
MASK% = 1 ' New Signal Bit has value 1
DO
CMD$ = "INR?"
CALL IBWRT (SCOPE%, CMD$)
CALL IBRD (SCOPE%, RD$)
NEWSIG% = VAL (RD$) AND MASK%
LOOP UNTIL NEWSIG% = MASK%
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Part 5: IEEE 488.2 Programming Reference
Serial Polling
Serial polling takes place once the SRQ interrupt line has been asserted, and is only advantageous when
you are using several oscilloscopes at once. The controller finds which oscilloscope has generated the
interrupt by inspecting the SRQ bit in the STB register of each. Because the service request is based on an
interrupt mechanism, serial polling offers a reasonable compromise in terms of servicing speed in
multiple-device configurations.
The following example uses the command INE 1 to enable the event "new signal acquired" for reporting
the INR to the INB bit of the status byte STB. The command *SRE 1 enables the INB of the status byte to
generate an SRQ whenever it is set. The function call IBWAIT instructs the computer to wait until one of
three conditions occurs:
l&H8000 in the mask (MASK%) corresponds to a GPIB error.
l&H4000 to a timeout error.
l&H0800 to the detection of RQS (ReQuest for Service) generated by the SRQ bit.
Whenever IBWAIT detects RQS, it automatically performs a serial poll to find out which oscilloscope
generated the interrupt. It only exits if a timeout occurs or if the oscilloscope (SCOPE%) generated SRQ.
The additional function call IBRSP fetches the value of the status byte, which may be further interpreted.
To work properly, the value of "Disable Auto Serial Polling" must be set to "off" in the GPIB handler (use
IBCONF.EXE to check).
Example: Serial Polling
CMD$ = "*CLS ; INE 1;*SRE 1"
CALL IBWRT (SCOPE%, CMD$)
MASK% = &HC800
CALL IBWAIT (SCOPE%, MASK%)
IF (IBSTA% AND &HC000) <> 0 THEN PRINT "GPIB or Timeout Error" : STOP
CALL IBRSP (SCOPE%, SPR%)
PRINT "Status Byte =.", SPR%
After the serial poll is completed, the RQS bit in the STB status register is cleared. Note that the other STB
register bits remain set until they are cleared by means of a *CLS command or the oscilloscope is reset. If
these bits are not cleared, they cannot generate another interrupt.
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MAUI Oscilloscopes Remote Control and Automation Manual
Parallel Polling
Like serial polling, this is only useful when several oscilloscopes are connected. The controller
simultaneously reads the Individual STatus bit (IST) of all oscilloscopes to determine which one needs
service. This method allows up to eight different oscilloscopes to be polled at the same time.
When a parallel poll is initiated, each oscilloscope returns a status bit over one of the DIO data lines.
Devices may respond either individually, using a separate DIO line, or collectively on a single data line.
Data-line assignments are made by the controller using a Parallel Poll Configure (PPC) sequence.
The following example uses the INE 1 command to enable the event "new signal acquired" in the INR for
reporting to the INB bit of the status byte STB. The PaRallel poll Enable register (PRE) determines which
events are summarized in the IST status bit. The command *PRE 1 enables the INB bit (when first set
itself) to set the IST bit. Once parallel polling is established, the parallel-poll status is examined until a
change on data bus line DIO2 takes place.
Example: Parallel Polling, Stage 1
Enable the INE and PRE registers; configure the controller for parallel poll; instruct the oscilloscope to
respond on data line 2 (DIO2) using these commands:
CMD1$ = DSOListenPCTalk$ 'As defined earlier
CALL IBCMD (BRD0%, CMD1$)
CMD$ = "INE 1;*PRE 1"
CALL IBWRT (BRD0%, CMD$)
PPE$ = Chr$ (&H5) 'GPIB Parallel Poll Enable
MSA9$ = Chr$ (&H69) 'GPIB Secondary Address 9
CMD4$ = PPE$ + MSA9$ + UnListen$
CALL IBCMD (BRD0%, CMD4$)
Example: Parallel Polling, Stage 2
Parallel poll the oscilloscope until DIO2 is set using these commands:
Do
CALL IBRPP (BRD0%, PPR%)
Loop Until (PPR% AND &H2) = 2
Example: Parallel Polling, Stage 3
Disable parallel polling (hex 15) and clear the parallel poll register using these commands:
PPU$ = Chr$ (&H15) 'GPIB Parallel Poll Unconfigure
CALL IBCMD (BRD0%, PPU$)
CALL IBCMD (BRD0%, CMD1$) 'As defined earlier
CMD$ = "*PRE 0" : CALL IBWRT(BRD0%,CMD$):
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Part 5: IEEE 488.2 Programming Reference
*IST Polling
Read the state of the Individual STatus bit (IST) returned during parallel polling by sending the *IST? query.
Enable this poll mode, by initializing the oscilloscope for parallel polling by writing into the PRE register.
Since *IST emulates parallel polling, apply this method wherever parallel polling is not supported by the
controller.
In the following example, the command INE 1 enables the event "new signal acquired" in the INR for
reporting to the INB bit of the status byte STB. The command *PRE 1 enables the INB bit (when first set
itself) to set the IST bit. The command CHDR OFF suppresses the command header in the oscilloscope's
response, simplifying the interpretation. The status of the IST bit is then continuously monitored until set
by the oscilloscope:
Example: *IST Polling
CMD$ = "CHDR OFF; INE 1; *PRE 1"
CALL IBWRT (SCOPE%, CMD$)
DO
CMD$ = "*IST?"
CALL IBWRT (SCOPE%, CMD$)
CALL IBRD (SCOPE%, RD$)
LOOP UNTIL VAL (RD$) = 1
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MAUI Oscilloscopes Remote Control and Automation Manual
Timing and Synchronization
Depending on how your remote program is written, it may be affected by timing changes between
different oscilloscopes. Most timing and synchronization problems are related to changing acquisitions, or
the completion of analysis after an acquisition occurs.
Say that you change the Offset of C1 while the oscilloscope is in Auto trigger mode, and then use the
PAVA? query to read a parameter computed on C1. In newer oscilloscopes, the processing is overlapped
with the next acquisition and, as a consequence, the PAVA? result may have come from the acquisition
prior to the offset change.
There are several ways to ensure your program provides correct results when remotely controlling the
oscilloscope.
Control the Trigger Mode
When in Single trigger mode, acquisitions do not overlap. You can use the status registers available in the
instrument, or the *OPC? query and the WAIT command to detect acquisition and processing completion.
When you arm the oscilloscope by sending the TRMD SINGLE command, the instrument automatically
performs any necessary calibrations before it acquires any data. These calibrations may take several
seconds, so if you query the status immediately after sending the TRMD SINGLE command, set the GPIB
(or remote) timeout to least 10 seconds and prevent a timeout before receiving the correct results.
A case where you may need to use Normal or Auto trigger mode involves the accumulation of many
acquisitions for averaging or histogramming functions. In this case, it is best to stop the acquisitions, set
up the oscilloscope, and then set the trigger mode to Normal when acquiring the data.
A possible alternative would be to use Sequence trigger mode. It is faster, but does require knowing how
many acquisitions to accumulate. This number can be specified and captured using sequence mode.
Reduce Calibrations
When operating in Dynamic Calibration mode, the default on older MAUI oscilloscopes, calibrations are
performed whenever your program changes some acquisition settings such as Volts/Div or the number of
active channels. Calibrations are also performed if the oscilloscope temperature significantly changed.
The calibrations may be disabled by sending the AUTO_CALIBRATE OFF command. While oscilloscope
performance may be degraded if the temperature changes and does not self-calibrate, a calibration can
always be forced by issuing the *CAL? command.
Using this forced calibration technique allows you to control their timing so they do not interfere while
acquiring important data.
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Part 5: IEEE 488.2 Programming Reference
Use Status Registers
Status registers store a record of events and conditions occurring inside the oscilloscope. Some of the
events recorded include:
lThe acquisition of new data
lWhen processing completes
lWhen printing (hardcopy) completes
lWhen an error occurs
Programmers can use the registers to sense the instrument's condition by polling until the desired status
bit is set. A status register can be polled by querying its associated remote command (*STB, INR?, *ESR).
Alternatively, the oscilloscope can request service from the controller by using the mask registers to select
the events of interest.
The following procedure shows the steps necessary for acquiring data using the status registers for
synchronization.
1. STOP the acquisition.
2. (Commands to) set up the oscilloscope.
3. Clear status registers.
4. Set up mask register (if needed).
5. ARM or TRMD SINGLE to start the acquisition.
6. Poll status registers or wait for service request.
(Various commands/queries) to read data, cursors, and parameter measurements.
If the data has already been acquired and you want to perform further analysis (math, parameters,
cursors), you can proceed as follows:
1. Clear status registers.
2. Set up mask register (if needed).
3. (Commands to) change math functions, parameters, cursors, etc. as required for analysis.
4. Poll status registers or wait for service request.
5. (Commands/queries to) read data, cursors, and parameter measurements.
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MAUI Oscilloscopes Remote Control and Automation Manual
Use *OPC? and WAIT
The acquisition WAIT command (not to be confused with the IEEE 488.2 standard *WAI command):
lWaits for the acquisition to complete, but does not wait for the processing.
lAllows you to specify an optional timeout so that if the oscilloscope does not trigger, your program
does not hang.
Note: If you use the timeout method, it is strongly advised to then check the status registers with
*OPC? to ensure the oscilloscope actually triggered and any processing has completed.
The *OPC? query returns a 1 when the previous commands have finished. This means you can use this
query with the WAIT command to synchronize the oscilloscope with your controller, using the procedure
shown here:
1. STOP the acquisition.
2. (Commands to) set up the oscilloscope.
3. ARM or TRMD SINGLE to start the acquisition.
4. WAIT for trigger and acquisition to complete.
5. *OPC? to ensure processing is complete.
6. (Commands/queries to) read data, cursors, and measurement parameters.
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Part 5: IEEE 488.2 Programming Reference
Waveform Transfer
A waveform can be said to have two main parts:
lIts basic data array: raw data values from the oscilloscope's ADCs (Analog-to-Digital Converters)
obtained during the waveform capture.
lThe description accompanying this raw data: vertical and horizontal scale or time of day, for
example, necessary for a full understanding of the information contained in the waveform.
When these parts are transmitted together, the descriptor comes first.
Waveform Template
Your instrument contains a Waveform Template that provides a detailed description of how this waveform
information is organized. Use the TEMPLATE? query to access the template on the oscilloscope itself (the
template may change as your oscilloscope's firmware is enhanced).
Remote Transfer
You can access the waveform descriptive information by remote control using the INSPECT? query, which
interprets it in ASCII text form. Waveform data can then be rapidly transferred off the oscilloscope using
the WAVEFORM? query, and written back into the oscilloscope with the WAVEFORM command.
Using the STORE and STORE_SETUP commands, you can also store waveform data in preformatted
ASCII output for popular spreadsheet and math processing packages.
Logical Data Blocks
Each waveform normally contains at least a Waveform Descriptor block and one data array block.
Additional blocks may also be present in more complex waveforms.
lWaveform Descriptor block (WAVEDESC) - This includes all the information necessary to
reconstitute the display of the waveform from the data, including hardware settings at the time of
acquisition, the exact time of the event, kinds of processing performed, your oscilloscope name and
serial number, the encoding format used for the data blocks, and miscellaneous constants.
lSequence Acquisition Times block (TRIGTIME) - This is needed for sequence mode acquisitions
to record the exact timing information for each segment. It contains the time of each trigger
relative to the trigger of the first segment, along with the time of the first data point of each
segment relative to its trigger.
lRandom Interleaved Sampling times block (RISTIME) - This is required for RIS acquisitions to
record the exact timing information for each segment.
lFirst Data Array block (SIMPLE or DATA_ARRAY_1) - This is the basic integer data of the
waveform. It can be raw or corrected ADC data or the integer result of waveform processing.
lSecond Data Array block (DATA_ARRAY_2) - This is a second data array, needed to hold the
results of processing functions such as the following Extrema of FFT math functions.
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MAUI Oscilloscopes Remote Control and Automation Manual
Array Extrema FFT
Data_Array_1 Roof trace Real part
Data_Array_2 Floor trace Imaginary part
Note: The Waveform Template may also describe an array named DUAL, but this is simply a way
to allow the INSPECT? query to examine two data arrays together.
Inspecting Waveform Contents
Use the INSPECT? query to examine the contents of your waveform.
The Waveform Template explains the WAVEDESC block and other logical blocks that may be returned by
the INSPECT? query. Use the TMPL? query to get a copy of the full Waveform Template in use on your
oscilloscope.
You can access a readable translation of single entities in the Waveform Descriptor block by using the
query INSPECT? "<WAVEDESC variable>". A typical exchange might be:
Query: C1:INSPECT? "VERTICAL_OFFSET"
Response: "VERTICAL_OFFSET: -4.0000e-002"
Query: C1:INSPECT? "TRIGGER_TIME"
Response: "TRIGGER_TIME: Date = APR 8, 2016, Time = 10:29: 0.311462573"
Also, use INSPECT? "SIMPLE" to examine the measured data values of a waveform. For example, the reply
to an acquisition with 52 points would look like the following:
INSPECT? "SIMPLE"
C1:INSP "
0.0005225 0.0006475 -0.00029 -0.000915 2.25001E-05 0.000835
0.0001475 -0.0013525 -0.00204 -4E-05 0.0011475 0.0011475
-0.000915 -0.00179 -0.0002275 0.0011475 0.001085 -0.00079
-0.00179 -0.0002275 0.00071 0.00096 -0.0003525 -0.00104
0.0002725 0.0007725 0.00071 -0.0003525 -0.00129 -0.0002275
0.0005225 0.00046 -0.00104 -0.00154 0.0005225 0.0012725
0.001335 -0.0009775 -0.001915 -0.000165 0.0012725 0.00096
-0.000665 -0.001665 -0.0001025 0.0010225 0.00096 -0.0003525
-0.000915 8.50001E-05 0.000835 0.0005225
"
The numbers in the previous table are the fully-converted measurements in volts.
Depending on the application, you may prefer the to see the data using either a BYTE (8 bits) or a WORD
(16 bits) for each data value. In that case, use INSPECT? "SIMPLE",BYTE or
INSPECT? "SIMPLE",WORD.
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Part 5: IEEE 488.2 Programming Reference
The examination of data values for waveforms with two data arrays can be performed as follows:
INSPECT? "DUAL" to get pairs of data values on a single line
INSPECT? "DATA_ARRAY_1" to get the values of the first data array
INSPECT? "DATA_ARRAY_2" to get the values of the second data array
INSPECT? has its limitations; it is useful, but wordy. INSPECT? cannot be used to quickly transfer an entire
waveform to and from the oscilloscope. To do this, use the WAVEFORM? query and WAVEFORM
command, instead. With WAVEFORM_SETUP, you can inspect a sparse form of the waveform.
If you are a BASIC user, you might also find it convenient to use INSPECT? and WAVEFORM? together to
construct files containing a version of the Waveform Descriptor that both you and BASIC can read. Using a
stored waveform, this can be done in a format suitable for retransfer to the instrument with MC:INSPECT?
"WAVEDESC";WAVEFORM?, and then placing the response directly into a file.
Using the Waveform Query
The WAVEFORM? query is an effective way to transfer waveform data in block formats defined by the
IEEE 488.2 standard. Responses can be downloaded back into the instrument by using the WAVEFORM
command.
All logical blocks in a waveform can be read with the simple query:
<trace>:WAVEFORM?
Your can also query for a single block by adding the block name as a parameter, for example:
C1:WAVEFORM? DAT1
The Waveform Template lists all the logical block names.
The response to the WAVEFORM? query of an oscilloscope in its default state will show the waveform
data in hexadecimal format with an ASCII translation.
Note: Waveform data read using the WFM? query can only be recalled back into internal memory
(M1 to Mx) on the oscilloscope. It may be beneficial to remove headers from the readout using the
COMM_HEADER command so that the data is ready to be copied to a .trc file and recalled as is. A
WFM? query response can easily contain over 16 million bytes if in binary form and twice as much
if the HEX option is used.
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MAUI Oscilloscopes Remote Control and Automation Manual
WFM? Response Compared to the Template
This example uses the result of the WAVEFORM? "WAVEDESC" query to show how the hexadecimal
response to a WAVEFORM? query maps to the WAVEDESC block description in the Waveform Template
(the response to TMPL?). Each element is numbered by raw byte and by offset, which is how it is identified
in the Waveform Template (where each block starts at byte 0), and color keyed to match the ASCII
translation.
Hexadecimal ASCII Translation
57 41 56 45 44 45 53 43 2C 23 39 30 30 32 30 30 WAVEDESC,#900200
30 33 34 38 57 41 56 45 44 45 53 43 00 00 00 00 0348WAVEDESC....
00 00 00 00 4C 45 43 52 4F 59 5F 32 5F 33 00 00 ....LECROY_2_3..
00 00 00 00 00 00 01 00 5A 01 00 00 00 00 00 00 ........Z.......
00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ................
82 84 1E 00 00 00 00 00 00 00 00 00 00 00 00 00 ................
4C 45 43 52 4F 59 57 61 76 65 52 75 6E 6E 65 72 LECROYWaveRunner
19 27 00 00 00 00 00 00 00 00 00 00 00 00 00 00 .'..............
Bytes Offset Color Contain
1 to 9 pink Simple beginning of a query response, translated into ASCII.
10 to 20 yellow String #9002000348, signaling the beginning of a binary block where nine ASCII
integers are used to give the length of the block (2000348 bytes).
21 to 36 0 blue Actual beginning of the waveform: 16-character block DESCRIPTOR_NAME string,
in this case WAVEDESC.
37 to 52 16 green TEMPLATE_NAME string, translated to LECROY_2_3.
53 to 54 32 purple COMM_TYPE byte, byte (0) or word (1), in this case byte.
55 to 56 34 purple
57 to 96 36 grey Length in bytes of forthcoming BLOCKS and ARRAYS. Because this example quer-
ied only the WAVEDESC block, most of the counts are zero.
97 to 112 76 orange 16-character INSTRUMENT_NAME string, translated to LECROYWaveRunner.
In this way you can use the Waveform Template to interpret the WAVEFORM? query readout.
Tip: Be sure to get the version of the Waveform Template on your oscilloscope using the TMPL?
query before beginning to make the mapping.
Interpreting Vertical Data
Knowing now how to decipher the data, you may wish to convert it to the appropriate measured values.
The vertical reading for each data point depends on the vertical gain and the vertical offset given in the
descriptor. For acquisition waveforms, this corresponds to the volts/div and voltage offset selected after
conversion for the data representation being used.
The template tells us that the vertical gain and offset can be found at Bytes 156 and 160 and are stored as
floating point numbers in the IEEE 32-bit format. An ASCII string giving the vertical unit is found in
VERTUNIT, byte 196 of the WAVEDESC block. The vertical value is given by the relationship:
value = VERTICAL_GAIN x data - VERTICAL_OFFSET
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Part 5: IEEE 488.2 Programming Reference
If the computer or the software available is not able to understand the IEEE floating point values, use the
description in the template.
The data values in a waveform may not correspond to measured points. FIRST_VALID_PNT and LAST_
VALID_PNT give the necessary information. The descriptor also records the SPARSING_FACTOR, the
FIRST_POINT, and the SEGMENT_INDEX to aid interpretation if the options of the WAVEFORM_SETUP
command have been used.
For sequence acquisitions, the data values for each segment are given in their normal order and the
segments are read out one after the other. The important descriptor parameters are the WAVE_ARRAY_
COUNT and the SUBARRAY_COUNT, giving the total number of points and the number of segments.
For waveforms such as the extrema and the complex FFT there are two arrays (one after the other) for
the two of the result.
Calculating the Horizontal Position of Data Points
Each vertical data value has a corresponding horizontal position, usually measured in time or frequency
units. The calculation of this position depends on the type of waveform. Each data value has a position, i, in
the original waveform, with i= 0 corresponding to the first data point acquired. The descriptor parameter
HORUNIT gives a string with the name of the horizontal unit.
Single Sweep Waveforms
x[i] = HORIZ_INTERVAL * i+ HORIZ_OFFSET
For acquisition waveforms this time is from the trigger to the data point in question. Its different from
acquisition to acquisition since the HORIZ_OFFSET is measured for each trigger.
Sequence Waveforms
These are really many independent acquisitions, so each segment has its own horizontal offset. These
can be found in the TRIGTIME array.
For the nth segment:
x[i,n] = HORIZ_INTERVAL * i+ TRIGGER_OFFSET[n]
The TRIGTIME array can contain up to 200 segments of timing information with two eight-byte double
precision floating point numbers for each segment.
RIS Waveforms
These are composed of many acquisitions interleaved together. The descriptor parameter, RIS_SWEEPS,
gives the number of acquisitions. The ith point belongs to the mth segment where:
m=imodulo (RIS_SWEEPS)
Has a value between 0 and RIS_SWEEPS -1.
Then with:
j=i-m
x[i] = x[j,m] = HORIZ_INTERVAL * j+ RIS_OFFSET[m]
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MAUI Oscilloscopes Remote Control and Automation Manual
where the RIS_OFFSET can be found in the RISTIME array. There can be up to 100 eight-byte double
precision floating point numbers in this block. The instrument tries to acquire segments with times such
that:
RIS_OFFSET[i] ≈ PIXEL_OFFSET + (i - 0.5) * HORIZ_INTERVAL
Decoding Floating Point Numbers
Single precision values are held in four bytes. If these are arranged in decreasing value order we get the
following bits:
bit 31, bit 30, bit 29, bit 28 . . . . . bit 3, bit 2, bit 1, bit 0
Note: If the byte order command CORD is set for low byte first, the bytes as received in a
waveform descriptor are received in reverse order. However, within a byte the bits keep their
order, highest at the left, as expected.
From these bits we are to construct three numbers that are to be multiplied together: S x E x F constructed
as follows:
S = (-1)sE = 2(e - 127) F = 1 + f
S, E, and F are calculated directly from the 32 bits. The following diagram illustrates the calculation of the
vertical gain example:
In a way not following the byte boundaries, bits are then segregated as follows:
31,30,29...............24,23,22,21.................2,1,0
sign exponent bits . . . . . . . fractional bits . . . . . . . . . . . . . . . . bit 0.5, 0.25, 0.125 . . .
The sign bit s is 1 for a negative number and 0 for a positive number, so it is easy to construct the sign from
this:
S = (-1)^s
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Part 5: IEEE 488.2 Programming Reference
The 8 exponent bits have the following values:
Bit 23 is worth 1, bit 24 is worth 2 . . . bit 29àis 64, bit 30 is 128, so the resulting number can range from 0 to
28 -1, which is 255.
127 is then subtracted from this value e creating a range from -127 to +128. This is then used as an
exponent to raise two to a power that is 2^e, to create a value E.
Then we have to create the multiplying number. The values of the 23 bits are as follows:
Bit 22 is worth 0.5, 21 is worth 0.25, 20 is worth 0.125, 19 is worth 0.0625 . . . .
When all the bits are added together, we obtain a positive number f that can be very close to one, differing
from it only by the value of the smallest bit, if all the bits are ones. (Generally the value will be much less
than one.) Then we add one to the result, obtaining 1 + f = F. The use of the added one extends the
dynamic range of the data. Another way of calculating f is to take the 23-bit number at face value, and
divide it by 2^24.
Finally we multiply together the sign, the value E, and the value F to create the final result:
Result = (-1)^s x 2^(e-127) x (1 + f) = S x E x F
Using The Waveform Command
Waveforms read with the WAVEFORM? query can be loaded back into the instrument using WAVEFORM
and related commands. Since the descriptor contains all of the necessary information, you don't need to
be concerned with communication format parameters. The oscilloscope learns all it needs to know from
the waveform.
Tip: Waveforms can only be sent back to the instrument memory traces (M1, M2, M3, M4).
Consider using the COMM_HEADER command to remove prefixes in the WFM? query response.
When synthesizing waveforms for display or comparison, always read out a waveform of the appropriate
size, and then replace the data with the desired values. This ensures the descriptor is coherent.
Here are some of the many ways to use WAVEFORM and its commands to simplify your work:
Partial Waveform Readout
Use WAVEFORM_SETUP to specify a short part of a waveform for readout and to select a sparsing factor
for reading only every nth data point.
Byte Swapping
The COMM_ORDER command allows you to swap two bytes of data presented in 16-bit word format, in
the descriptor or in the data/time arrays, when sending the data via GPIB or LAN ports. Depending on the
computer system used, this allows easier data interpretation.
For Intel-based computers, you should send the data with the LSB first; the command should be CORD LO.
For Motorola-based computers, send the data with the MSB first (CORD HI), the default at power-up.
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MAUI Oscilloscopes Remote Control and Automation Manual
Note: Data written to the instrument's hard disk, USB, or floppy always remain in LSB first format
(the default DOS format). You cannot use the CORD command in these cases, since it is only
meant for data sent using GPIB and RS-232-C ports.
Data Length, Block Format, and Encoding
COMM_FORMAT gives you control over these parameters. If you do not need the extra precision of the
lower order byte of the standard data value, the BYTE option enables you to save the amount of data
transferred or stored by a factor of two. If the computer you are using cannot read binary data, the HEX
option allows a response form where the value of each byte is given by a pair of hexadecimal digits.
Data-Only Transfers
COMM_HEADER OFF enables a response to WF? DAT1 with data only (the C1:WF DAT1 disappears). If you
have also specified COMM_FORMAT OFF,BYTE,BIN, the response is in data bytes only (the #90000nnnnn
disappears). Refer to the table in Using the Waveform Query for more information.
Transferring High-Speed Waveforms
Several important factors must be considered to achieve maximum, continuous data transfer rates from
your instrument to the external controller.
The single most important of these is to limit the amount of work done by the computer, meaning:
lAvoid writing data to disk wherever possible
lMinimize operations such as per-data-point computations
lReduce the number of calls to the I/O system
To do this, try the following:
lReduce the number of points to be transferred and the number of data bytes per point. The
pulse parameter capability and the processing functions can save a great deal of computing and a
lot of data transfer time if employed creatively.
lAttempt to overlap waveform acquisition with waveform transfer. The oscilloscope is capable of
transferring an already acquired or processed waveform after a new acquisition has been started.
The total time the instrument takes to acquire events is considerably increased if it is set to wait for
triggers (live time).
lMinimize the number of waveform transfers by using Sequence mode to accumulate many
triggers for each transfer. This is preferable to using WAVEFORM_SETUP to reduce the number of
data points for transfer. It also significantly reduces oscilloscope transfer overhead. For example,
you could use ARM; WAIT;C1:WF? to wait for the event, transfer the data, and then start a new
acquisition. You could also loop this line in the program as soon as it has finished reading the
waveform.
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Part 6: IEEE 488.2 Command Reference
Part 6: IEEE 488.2 Command Reference
Throughout this reference, the full command header is listed first, followed by the short form, as in
DOT_JOIN,DTJN. Either form may be used in commands and queries.
The solution to unavailable legacy commands is to use Automation commands integrated into a 488.2
remote control program using the VBS command.
Commands and Queries by Short Form 6-2
Commands and Queries by Subsystem 6-8
ACQUISITION Commands and Queries 6-15
AUTOMATION Commands and Queries 6-43
COMMUNICATION Commands and Queries 6-44
CURSOR Commands and Queries 6-50
DISPLAY Commands and Queries 6-75
FUNCTION Commands and Queries 6-90
HARDCOPY Commands and Queries 6-101
MISCELLANEOUS Commands and Queries 6-104
PROBE Commands 6-112
SAVE/RECALL SETUP Commands and Queries 6-119
STATUS Commands and Queries 6-125
STORAGE Commands and Queries 6-144
WAVEFORM TRANSFER Commands and Queries 6-146
DISK DRIVE ANALYSIS (Option) Commands and Queries 6-156
ET-PMT (Option) Commands and Queries 6-201
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MAUI Oscilloscopes Remote Control and Automation Manual
Commands and Queries by Short Form
Short Long Subsystem What The Command or Query Does
3DB DD_CTAF_3DB DDA Sets the CTAF parameter, 3 dB.
ACAL AUTO_CALIBRATE MISC Enables and disables automatic calibration.
ALST? ALL_STATUS? STATUS Reads and clears the contents of all status registers.
ARM ARM_ACQUISITION ACQUISITION Changes acquisition mode from Stopped to Single.
ASET AUTO_SETUP ACQUISITION Adjusts vertical, timebase and trigger parameters.
ATTN ATTENUATION ACQUISITION Selects the vertical attenuation factor of the probe.
BUZZ BUZZER MISC Controls the buzzer in the instrument.
BWL BANDWIDTH_LIMIT ACQUISITION Enables/disables bandwidth-limiting low-pass filter.
*CAL? *CAL? MISC Performs a complete internal calibration of the instru-
ment.
CFMT COMM_FORMAT COMM Selects the format for sending waveform data.
CHDR COMM_HEADER COMM Controls formatting of query responses.
CHL COMM_HELP_LOG COMM Returns the contents of the RC Assistant log.
CHLP COMM_HELP COMM Controls operational level of the RC Assistant.
CLM CLEAR_MEMORY FUNCTION Clears the specified memory.
*CLS *CLS STATUS Clears all status data registers.
CLSW CLEAR_SWEEPS FUNCTION Restarts the cumulative processing functions.
CMR? CMR? STATUS Reads and clears the CoMmand error Register (CMR).
COMB COMBINE_CHANNELS ACQUISITION Controls the channel interleaving function.
CORD COMM_ORDER COMM Controls the byte order of waveform data transfers.
COUT CAL_OUTPUT MISC Sets signal type put out at the CAL connector.
CPL COUPLING ACQUISITION Selects the specified input channel's coupling mode.
CRMS CURSOR_MEASURE CURSOR Specifies the type of cursor/parameter measurement.
CRS CURSORS CURSOR Sets the cursor type.
CRST CURSOR_SET CURSOR Allows positioning of any cursor.
CRVA? CURSOR_VALUE? CURSOR Returns trace values measured by specified cursors.
CUAP CUSTOM_APPLICATION ET-PMT Toggles between Mask Tester and oscilloscope mode.
CU_OPT? CUSTOM_OPTIONS? ET-PMT Returns installed custom options.
DACT DD_ANALOG_COMP_THRESH DDA Sets the analog threshold value for Analog Compare.
DARD DD_ANALYZE_REGION_DISABLE DDA Disables the use of the analyze region markers.
DARL DD_ANALYZE_REGION_LENGTH DDA Selects the length of a region to be analyzed.
DARS DD_ANALYZE_REGION_START DDA Selects the start of a region to be analyzed.
DATE DATE MISC Changes the date/time of the internal real-time clock.
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Part 6: IEEE 488.2 Command Reference
Short Long Subsystem What The Command or Query Does
DBIT DD_BITCELL DDA Enters the bit cell time of the head signal.
DBST DD_CTAF_BOOST DDA Sets the CTAF parameter, boost.
DBYT DD_BYTE_OFFSET DDA Moves the head trace to show the specified byte.
DDFC DD_CTAF_FC DDA Sets the CTAF parameter, cut-off frequency fc.
DDFM DD_FIND_METHOD DDA Selects the error-finding method.
DDR? DDR? STATUS Reads, clears the Device Dependent Register (DDR).
DDSI DD_SIGNAL_INPUT DDA Sends or reads out the association of a source with a
particular Disk Drive signal.
DEF DEFINE FUNCTION Specifies math expression for function evaluation.
DELF DELETE_FILE STORAGE Deletes a file from the currently selected directory.
DENC DD_ENCODING DDA Allows selection of the data-encoding ratio for locating
the bytes by byte offset.
DERI? DD_ERR_INFO DDA Returns the measured value associated with the last
error position selected, and a code specifying what the
value contains.
DERR DD_ERR_NUM DDA Displays the section of waveform containing the
specified error number.
DFBIT DD_FIND_BITCELL DDA Looks at the head signal and attempts to determine the
bit-cell time.
DFEN DD_FIR_ENABLE DDA Enables the FIR filter for PRML channel emulation.
DFER DD_FIND_ERROR DDA Commands the DDA to find errors.
DFGD DD_CTAF_GROUP_DELAY DDA Sets the CTAF parameter, group delay.
DFIR DD_FIR DDA Stores the setup that will be used if the FIR filter is
enabled for use in the channel emulation.
DHSC DD_HEADSIGNAL_CHANNEL DDA Specifies the head signal source channel or memory
for channel emulation and servo analysis.
DIGS DD_IGNORE_SAMPLES DDA Defines the number of samples to be ignored at the
Read Gate signal end for channel emulation and ana-
log compare.
DISP DISPLAY DISPLAY Controls the display screen.
DNER? DD_NUM_ERRORS DDA Returns the number of errors found.
DOVL DD_OVERLAP_REF DDA sets a state variable which determines re-estab-
lishing the overlap of the head signal
DPA DD_PES_ANALYSIS DDA Starts or aborts PES analysis.
DPD? DD_PES_DATA DDA Reads out results of PES Analysis.
DPSD? DD_PES_SUMMARY_DATA DDA Summarizes PES Analysis results.
DPSU DD_PES_SETUP DDA Command sets parameters for PES Analysis. The
query responds with the current state of specified
keywords.
DRAV DD_RESET_AVERAGE DDA Resets the averaged data and all sweeps; clears his-
tograms and parameters; allows the start of a fresh ana-
lysis.
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MAUI Oscilloscopes Remote Control and Automation Manual
Short Long Subsystem What The Command or Query Does
DRCC DD_READCLOCK_CHANNEL DDA Specifies the input channel to which Read Clock is con-
nected or the memory in which it is stored.
DRGC DD_READGATE_CHANNEL DDA Specifies the input channel to which Read Gate is con-
nected or the memory in which it is stored.
DRGP DD_READ_GATE_POLARITY DDA Selects the polarity of the Read Gate signal.
DRLE DD_ML_RUN_LENGTH_LIMIT DDA Limits the run length, the number of “0” values in a row
for the head/analog signal when channel emulation is
active.
DRLM DD_ML_MIN_SPACING DDA When channel emulation is active, this sets the min-
imum allowed spacing of transitions.
DSAV DD_START_AVERAGING DDA Changes the state of the “Avg. Samples” switch on the
Graph menu.
DSEG DD_BYTE_OFFSET_SEGMENT DDA Moves the head trace to show the specified segment.
DSF DD_SHOW_FILTERED DDA Enables and disables the filtering of the head signal.
DSIG DD_SIGNAL_TYPE DDA Specifies Peak Detect or a particular PRML format for
the head signal.
DSLV DD_SHOW_LEVELS DDA Displays the level markers indicating the Viterbi levels
of the ML samples when channel emulation is active.
DSML DD_SHOW_ML DDA Displays/hides ML markers
DSPH DD_SAMPLE_PHASE DDA Adjusts the phase between the DDFA PLL sample
points and an external clock reference (when RCLK is
connected).
DSST DD_SHOW_SAMPLE_TIMES DDA Shows vertical-line cursors on the grid at each sample
time corresponding to the read clock.
DST DD_SAM_THRESH DDA Sets the SAM threshold value for channel emulation.
DSTR DD_STORE_REFERENCE DDA Stores the head signal to one of the DDA’s available
memories for analog compare and channel emulation
with reference.
DTF? DD_TRAIN_FILTER DDA Commands the DDA to determine reasonable values
for each filter parameter.
DTJN DOT_JOIN DISPLAY Controls the interpolation lines between data points.
DVSP DD_VCO_SYNCH_PATTERN DDA Defines the number of bits per half-period in the syn-
chronization field.
DVTD DD_VCOSYNCH_TO_DATA DDA Specifies the number of bytes on the analog head sig-
nal waveform between the end of the VCO sync field
and the actual data.
*ESE *ESE STATUS Sets the Standard Event Status Enable register (ESE).
*ESR? *ESR? STATUS Reads, clears the Event Status Register (ESR).
EXR? EXR? STATUS Reads, clears the EXecution error Register (EXR).
FCR FIND_CENTER_RANGE FUNCTION Automatically sets the center and width of a histogram.
FRST FUNCTION_RESET FUNCTION Resets a waveform-processing function.
FRTR FORCE_TRIGGER ACQUISITION Forces the instrument to make one acquisition.
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Part 6: IEEE 488.2 Command Reference
Short Long Subsystem What The Command or Query Does
GRID GRID DISPLAY Specifies single-, dual- or quad-mode grid display.
HCSU HARDCOPY_SETUP HARD COPY Configures the hard-copy driver.
HMAG HOR_MAGNIFY DISPLAY Horizontally expands the selected expansion trace.
HPOS HOR_POSITION DISPLAY Horizontally positions intensified zone's center.
*IDN? *IDN? MISC Causes instrument to respond with identifiers.
INE INE STATUS Sets the Internal state change Enable register (INE).
INR? INR? STATUS Reads, clears Internal state change Register (INR).
INSP? INSPECT? WAVEFORM
TRANSFER
Allows acquired waveform parts to be read.
ILVD INTERLEAVED ACQUISITION Enables/disables Random Interleaved Sampling (RIS).
INTS INTENSITY DISPLAY Controls the brightness of the grid.
IST? IST? STATUS Reads the current state of the IEEE 488.
MSG MESSAGE DISPLAY Displays a character string on the instrument screen.
MSIZ MEMORY_SIZE ACQUISITION Selects max. memory length.
MTFA MT_FAIL_ACTION ET-PMT Sets fail actions.
MTOF MT_OFFSET ET-PMT Sets the offset for STM-1E, STS-3E, and 139M.
MTOP? MT_OPC? ET-PMT Returns state of last operation.
MTPC? MT_PF_COUNTERS? ET-PMT Returns pass/fail result.
MTST MT_SELECT_TEST ET-PMT Selects Electrical Telecomm testing standard.
MTSY? MT_SYMBOL? ET-PMT Returns 1 or 0 symbol, or pos or neg.
MTTS MT_TEST_STATE ET-PMT Controls testing status: RUN, STOP, PAUSE,
CONTINUE.
MTVA MT_VERTICAL_ALIGN ET-PMT Performs offset alignment for STM-1E, STS-3E, and
139M.
OFCT OFFSET_CONSTANT CURSOR Sets offset to be fixed in either divisions or volts.
OFST OFFSET ACQUISITION Allows output channel vertical offset adjustment.
*OPC *OPC STATUS Sets the OPC bit in the Event Status Register (ESR).
*OPT? *OPT? MISC Identifies oscilloscope options.
PACL PARAMETER_CLR CURSOR Clears all current parameters in Custom, Pass/Fail.
PACU PARAMETER_CUSTOM CURSOR Controls parameters with customizable qualifiers.
PADL PARAMETER_DELETE CURSOR Deletes a specified parameter in Custom, Pass/Fail.
PARM PARAMETER CURSOR Controls the parameter mode.
PAST? PARAMETER_STATISTICS? CURSOR Returns parameter statistics results.
PAVA? PARAMETER_VALUE? CURSOR Returns current parameter, mask test values.
PECL PERSIST_COLOR DISPLAY Controls color rendering method of persistence traces.
PECS PER_CURSOR_SET CURSOR Positions one of the six independent cursors.
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Short Long Subsystem What The Command or Query Does
PELT PERSIST_LAST DISPLAY Shows the last trace drawn in a persistence data map.
PERS PERSIST DISPLAY Enables or disables the persistence display mode.
PESA PERSIST_SAT DISPLAY Sets the color saturation level in persistence.
PESU PERSIST_SETUP DISPLAY Selects display persistence duration.
PF PASS_FAIL CURSOR Sets up pass fail system.
PFDO PASS_FAIL_DO CURSOR Defines outcome and actions for Pass/Fail
PNSU PANEL_SETUP SAVE/RECALL Complements the *SAV/*RST commands.
*PRE *PRE STATUS Sets the PaRallel poll Enable register (PRE).
*RCL *RCL SAVE/RECALL Recalls one of five non-volatile panel setups.
RCLK REFERENCE_CLOCK ACQUISITION Toggles between internal clock and external clock.
RCPN RECALL_PANEL SAVE/RECALL Recalls a front panel setup from mass storage.
*RST *RST SAVE/RECALL Initiates a device reset.
*SAV *SAV SAVE/RECALL Stores current state in non-volatile internal memory.
SCDP SCREEN_DUMP HARD COPY Initiates a screen capture.
SCLK SAMPLE_CLOCK ACQUISITION Toggles between internal clock and external clock.
SEQ SEQUENCE ACQUISITION Controls the sequence mode of acquisition.
*SRE *SRE STATUS Sets the Service Request Enable register (SRE).
*STB? *STB? STATUS Reads the contents of the IEEE 488.
STO STORE WAVEFORM
TRANSFER
Stores a trace in internal memory or mass storage.
STOP STOP ACQUISITION Immediately stops signal acquisition.
STPN STORE_PANEL SAVE/RECALL Stores front panel setup to mass storage.
STST STORE_SETUP WAVEFORM
TRANSFER
Sets up waveform storage.
TDIV TIME_DIV ACQUISITION Modifies the timebase setting.
TMPL? TEMPLATE? WAVEFORM
TRANSFER
Produces a complete waveform template copy.
TRA TRACE DISPLAY Enables or disables the display of a trace.
TRCP TRIG_COUPLING ACQUISITION Sets the coupling mode of the specified trigger source.
TRFL TRANSFER_FILE WAVEFORM
TRANSFER
Transfers ASCII files to and from storage media, or
between scope and computer.
TRDL TRIG_DELAY ACQUISITION Sets the time at which the trigger is to occur.
*TRG *TRG ACQUISITION Executes an ARM command.
TRLV TRIG_LEVEL ACQUISITION Adjusts the trigger level of the specified trigger source.
TRMD TRIG_MODE ACQUISITION Specifies the trigger mode.
TRPA TRIG_PATTERN ACQUISITION Defines a trigger pattern.
TRSE TRIG_SELECT ACQUISITION Selects the condition that will trigger acquisition.
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Part 6: IEEE 488.2 Command Reference
Short Long Subsystem What The Command or Query Does
TRSL TRIG_SLOPE ACQUISITION Sets the trigger slope of the specified trigger source.
*TST? *TST? MISC Performs internal self-test.
VBS VBS AUTOMATION Sends an automation command.
VDIV VOLT_DIV ACQUISITION Sets the vertical sensitivity.
VMAG VERT_MAGNIFY DISPLAY Vertically expands the specified trace.
VPOS VERT_POSITION DISPLAY Adjusts the vertical position of the specified trace.
*WAI *WAI STATUS WAIt to continue - required by the IEEE 488.
WAIT WAIT ACQUISITION Prevents new analysis until current is completed.
WF WAVEFORM WAVEFORM
TRANSFER
Transfers a waveform from controller to scope.
WFSU WAVEFORM_SETUP WAVEFORM
TRANSFER
Specifies amount of waveform data to go to controller.
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Commands and Queries by Subsystem
ACQUISITION - Controlling Waveform Captures
Short Long What The Command or Query Does
ARM ARM_ACQUISITION Changes acquisition state from stopped to single.
ASET AUTO_SETUP Adjusts vertical, timebase and trigger parameters.
ATTN ATTENUATION Selects the vertical attenuation factor of the probe.
BWL BANDWIDTH_LIMIT Enables/disables bandwidth-limiting low-pass filter.
COMB COMBINE_CHANNELS Controls the channel interleaving function.
CPL COUPLING Selects the specified input channel's coupling mode.
FRTR FORCE_TRIGGER Forces the instrument to make one acquisition.
ILVD INTERLEAVED Enables/disables Random Interleaved Sampling (RIS).
MSIZ MEMORY_SIZE Selects max. memory length.
OFST OFFSET Allows output channel vertical offset adjustment.
RCLK REFERENCE_CLOCK Toggles between internal clock and external clock.
SCLK SAMPLE_CLOCK Toggles between internal clock and external clock.
SEQ SEQUENCE Controls the sequence mode of acquisition.
STOP STOP Immediately stops signal acquisition.
TDIV TIME_DIV Modifies the timebase setting.
TRCP TRIG_COUPLING Sets the coupling mode of the specified trigger source.
TRDL TRIG_DELAY Sets the time at which the trigger is to occur.
*TRG *TRG Executes an ARM command.
TRLV TRIG_LEVEL Adjusts the trigger level of the specified trigger source.
TRMD TRIG_MODE Specifies the trigger mode.
TRPA TRIG_PATTERN Defines a trigger pattern.
TRSE TRIG_SELECT Selects the condition that will trigger acquisition.
TRSL TRIG_SLOPE Sets the trigger slope of the specified trigger source.
VDIV VOLT_DIV Sets the vertical sensitivity.
WAIT WAIT Prevents new analysis until current is completed.
AUTOMATION - Sending Automation Commands
Short Long What The Command or Query Does
VBS VBS Sends Automation commands.
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Part 6: IEEE 488.2 Command Reference
COMMUNICATION - Setting Communication Characteristics
Short Long What The Command or Query Does
CFMT COMM_FORMAT Selects the format for sending waveform data.
CHDR COMM_HEADER Controls formatting of query responses.
CHL COMM_HELP_LOG Returns the contents of the RC Assistant log.
CHLP COMM_HELP Controls operational level of the RC Assistant.
CORD COMM_ORDER Controls the byte order of waveform data transfers.
CURSOR - Performing Measurements
Short Long What The Command or Query Does
CRMS CURSOR_MEASURE Specifies the type of cursor/parameter measurement.
CRS CURSORS Sets the cursor type.
CRST CURSOR_SET Allows positioning of any cursor.
CRVA? CURSOR_VALUE? Returns trace values measured by specified cursors.
OFCT OFFSET_CONSTANT Sets offset to be fixed in either divisions or volts.
PACL PARAMETER_CLR Clears all current parameters in Custom, Pass/Fail.
PACU PARAMETER_CUSTOM Controls parameters with customizable qualifiers.
PADL PARAMETER_DELETE Deletes a specified parameter in Custom, Pass/Fail.
PARM PARAMETER Controls the parameter mode, Standard, Custom, etc.
PAST? PARAMETER_STATISTICS? Returns parameter statistics results.
PAVA? PARAMETER_VALUE? Returns current parameter, mask test values.
PECS PER_CURSOR_SET Positions one of the six independent cursors.
PF PASS_FAIL Sets up pass fail system.
PFDO PASS_FAIL_DO Defines outcome and actions for Pass/Fail tests.
DISPLAY - Displaying Waveforms
Short Long What The Command or Query Does
DISP DISPLAY Controls the display screen.
DTJN DOT_JOIN Controls the interpolation lines between data points.
GRID GRID Specifies single-, dual- or quad-mode grid display.
HMAG HOR_MAGNIFY Horizontally expands the selected expansion trace.
HPOS HOR_POSITION Horizontally positions intensified zone's center.
INTS INTENSITY Controls the brightness of the grid.
MSG MESSAGE Displays a character string on the instrument screen.
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Short Long What The Command or Query Does
PECL PERSIST_COLOR Controls color rendering method of persistence traces.
PELT PERSIST_LAST Shows the last trace drawn in a persistence data map.
PERS PERSIST Enables or disables the persistence display mode.
PESA PERSIST_SAT Sets the color saturation level in persistence.
PESU PERSIST_SETUP Selects display persistence duration.
TRA TRACE Enables or disables the display of a trace.
VMAG VERT_MAGNIFY Vertically expands the specified trace.
VPOS VERT_POSITION Adjusts the vertical position of the specified trace.
FUNCTION - Performing Waveform Mathematical Operations
Short Long What The Command or Query Does
CLM CLEAR_MEMORY Clears the specified memory.
CLSW CLEAR_SWEEPS Restarts the cumulative processing functions.
DEF DEFINE Specifies math expression for function evaluation.
FCR FIND_CENTER_RANGE Automatically sets the center and width of a histogram.
FRST FUNCTION_RESET Resets a waveform-processing function.
HARDCOPY - Printing the Display/Screen Capture
Short Long Form What The Command or Query Does
HCSU HARDCOPY_SETUP Configures the hard-copy driver.
SCDP SCREEN_DUMP Initiates a screen dump.
MISCELLANEOUS
Short Long What The Command or Query Does
ACAL AUTO_CALIBRATE Enables and disables automatic calibration.
BUZZ BUZZER Controls the buzzer in the instrument.
*CAL? *CAL? Performs a complete internal calibration of the DSO.
COUT CAL_OUTPUT Sets signal type put out at the CAL connector.
DATE DATE Changes the date/time of the internal real-time clock.
*IDN? *IDN? For identification purposes.
*OPT? *OPT? Identifies oscilloscope options.
*TST? *TST? Performs internal self-test.
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Part 6: IEEE 488.2 Command Reference
PROBES - Using Probes
Short Long What The Command or Query Does
PRIT? PROBE_INFOTEXT? Returns attributes of a connected probe.
PRNA? PROBE_NAME Identifies a probe connected to the instrument.
PRx:AZ PRx:AUTOZERO Initiates an AutoZero cycle in an ADP30x probe.
PRx:BWL PRx:BANDWIDTH_LIMIT Sets the upper (HF) 3 dB bandwidth limit of an ADP305 probe.
PRx:CPL PRx:COUPLING Selects the coupling mode of an ADP30x probe.
PRx:OFST PRx:OFFSET Sets the probe offset value of an ADP30x probe.
PRx:VDIV PRx:VOLT_DIV Sets the vertical sensitivity at an ADP30x probe input.
SAVE/RECALLSETUP - Perserving and Restoring Panel Settings
Short Long What The Command or Query Does
PNSU? PANEL_SETUP? Returns panel setups in ASCII format.
*RCL *RCL Recalls one of five non-volatile panel setups.
RCPN RECALL_PANEL Recalls a panel setup from mass storage.
*RST *RST Initiates a device reset.
*SAV *SAV Stores current state in non-volatile internal memory.
STPN STORE_PANEL Stores a panel setup to mass storage.
STATUS - Obtaining Status Information and Setup Service Requests
Short Long What The Command or Query Does
ALST? ALL_STATUS? Reads and clears the contents of all status registers.
*CLS *CLS Clears all status data registers.
CMR? CMR? Reads and clears the CoMmand error Register (CMR).
DDR? DDR? Reads and clears the Device Dependent Register (DDR).
*ESE *ESE Sets the Standard Event Status Enable register (ESE).
*ESR? *ESR? Reads and clears the Event Status Register (ESR).
EXR? EXR? Reads and clears the EXecution error Register (EXR).
INE INE Sets the INternal state change Enable register (INE).
INR? INR? Reads and clears INternal state change Register (INR).
IST? IST? Reads the current state of the IEEE 488.
*OPC *OPC Sets the OPC bit in the Event Status Register (ESR).
*PRE *PRE Sets the PaRallel poll Enable register (PRE).
*SRE *SRE Sets the Service Request Enable register (SRE).
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Short Long What The Command or Query Does
*STB? *STB? Reads the contents of the IEEE 488.
*WAI *WAI WAIt to continue - required by the IEEE 488.
STORAGE
Short Long What The Command or Query Does
DELF DELETE_FILE Deletes files from mass storage directory.
TRFL TRANSFER_FILE Allows for transferring files to and from storage media, or between
oscilloscope and computer.
WAVEFORM TRANSFER - Preserving and Restoring Waveforms
Short Long What The Command or Query Does
INSP? INSPECT? Allows acquired waveform parts to be read.
REC RECALL Recalls waveform from mass storage to internal memory.
STO STORE Stores a waveform in internal memory or mass storage.
STST STORE_SETUP Controls the way in which waveforms are stored.
TMPL? TEMPLATE? Produces a copy of the template describing a complete waveform.
WF WAVEFORM Query transfers a waveform from oscilloscope to controller in re-load-
able format; command transfers a waveform read using WF? from
controller to scope.
WFSU WAVEFORM_SETUP Specifies amount of waveform data to go to controller.
DISK DRIVE ANALYSIS (Option) — Specialized Disk Drive Measurements
Short Long What The Command or Query Does
3DB DD_CTAF_3DB Sets the CTAF parameter, 3 dB.
DACT DD_ANALOG_COMP_THRESH Sets the analog threshold value for DDA analog compare.
DARD DD_ANALYZE_REGION_DISABLE Disables the use of the DDA analyze region markers.
DARL DD_ANALYZE_REGION_LENGTH Selects the length of a region to be analyzed by DDA.
DARS DD_ANALYZE_REGION_START Selects the start of a region to be analyzed by DDA.
DBIT DD_BITCELL Enters the bit cell time of the drive head signal.
DBST DD_CTAF_BOOST Sets the DDA CTAF parameter, boost.
DBYT DD_BYTE_OFFSET Moves the head trace to show the specified byte in DDA.
DDFC DD_CTAF_FC Sets the DDA CTAF parameter, cut-off frequency fc.
DDFM DD_FIND_METHOD Selects the DDA error-finding method.
DDSI DD_SIGNAL_INPUT Sends or reads out the association of a particular Disk Drive signal
with a source.
DENC DD_ENCODING Allows selection of the data-encoding ratio for locating the bytes by
byte offset in DDA.
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Part 6: IEEE 488.2 Command Reference
Short Long What The Command or Query Does
DERI? DD_ERR_INFO? Returns the measured value associated with the last DDA error pos-
ition selected, and a code specifying what the value contains.
DERR DD_ERR_NUM Displays the section of waveform containing the specified DDA error
number.
DFBIT? DD_FIND_BITCELL? Looks at the head signal and attempts to determine the bit-cell time.
DFEN DD_FIR_ENABLE Enables the FIR filter for PRML channel emulation.
DFER DD_FIND_ERROR Commands the DDA to find errors.
DFGD DD_CTAF_GROUP_DELAY Sets the DDA CTAF parameter, group delay.
DFIR DD_FIR Stores the setup that will be used if the FIR filter is enabled for use in
the channel emulation.
DHSC DD_HEADSIGNAL_CHANNEL Specifies the head signal source channel or memory for channel
emulation and servo analysis.
DIGS DD_IGNORE_SAMPLES Defines number of samples to be ignored at the Read Gate signal
end for channel emulation and analog compare.
DNER? DD_NUM_ERRORS Gives the number of DDA errors found.
DOVL DD_OVERLAP_REF Sets a state variable that determines whether the DDA
re-establishes the overlap of the reference signal whenever the
head trace is moved.
DPA DD_PES_ANALYSIS Starts/aborts PES analysis.
DPD? DD_PES_DATA? Reads out results of PES Analysis.
DPSD? DD_PES_SUMMARY_DATA? Summarizes PES Analysis results.
DPSU DD_PES_SETUP Sets parameters for PES Analysis.
DRAV DD_RESET_AVERAGE Resets the averaged data and all sweeps; clears histograms and
parameters.
DRCC DD_READCLOCK_CHANNEL Specifies the input channel to which Read Clock is connected or the
memory in which it is stored.
DRGC DD_READGATE_CHANNEL Specifies the input channel to which Read Gate is connected or the
memory in which it is stored.
DRGP DD_READ_GATE_POLARITY Selects the polarity of the read gate signal.
DRLE DD_ML_RUN_LENGTH_LIMIT Limits the run length.
DRLM DD_ML_MIN_SPACING Sets the minimum allowed transitions.
DSAV DD_START_AVERAGING Changes the state of the “Avg. Samples” switch on the Graph menu.
DSEG DD_BYTE_OFFSET_SEGMENT Moves the head trace to show the specified segment in DDA.
DSF DD_SHOW_FILTERED Enables and disables the filtering of the head signal.
DSIG DD_SIGNAL_TYPE Specifies Peak Detect or a particular PRML format for the head
signal.
DSLV DD_SHOW_LEVELS Displays the level markers indicating the Viterbi levels of the ML
samples when channel emulation is active.
DSML DD_SHOW_ML Displays ML markers.
DSPH DD_SAMPLE_PHASE Adjusts the phase between the DDFA PLL sample points and an
external clock reference (when RCLK is connected).
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Short Long What The Command or Query Does
DSST DD_SHOW_SAMPLE_TIMES Shows vertical-line cursors on the grid at each sample time
corresponding to the read clock.
DST DD_SAM_THRESH Sets the SAM threshold value for channel emulation.
DSTR DD_STORE_REFERENCE Stores the head signal to one of the DDA’s available memories for
analog compare and channel emulation with reference.
DTF DD_TRAIN_FILTER Commands the DDA to determine reasonable values for each filter
parameter.
DVSP DD_VCO_SYNCH_PATTERN Defines the number of bits per half-period in the synchronization
field.
DVTD DD_VCOSYNCH_TO_DATA Specifies the number of bytes on the analog head signal waveform
between the end of the VCO sync field and the actual data.
ET-PMT (Option) - Electrical Telecomm Pulse Mask Testing
Short Long What The Command or Query Does
CU_OPT? CUSTOM_OPTIONS? Returns installed custom options.
CUAP CUSTOM_APPLICATION Toggles between Mask Tester mode and oscilloscope mode.
MTFA MT_FAIL_ACTION Sets fail actions.
MTOF MT_OFFSET Sets the offset for STM-1E, STS-3E, and 139M.
MTOP? MT_OPC? Returns state of last operation.
MTPC? MT_PF_COUNTERS? Returns pass/fail result.
MTST MT_SELECT_TEST Selects Electrical Telecomm testing standard.
MTSY? MT_SYMBOL? Returns 1 or 0 symbol, or pos or neg.
MTTS MT_TEST_STATE Controls testing status: RUN, STOP, PAUSE, CONTINUE.
MTVA MT_VERTICAL_ALIGN Performs offset alignment for STM-1E, STS-3E, and 139M.
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Part 6: IEEE 488.2 Command Reference
ACQUISITION Commands and Queries
ARM_ACQUISITION, ARM
Description
The ARM_ACQUISITION command arms the scope and forces a single acquisition if it is already armed.
Command Syntax
ARM_ACQUISITION
Example (GPIB)
The following instruction enables signal acquisition:
CMD$="ARM": CALL IBWRT(SCOPE%,CMD$)
Related Commands
STOP, *TRG, TRIG_MODE, WAIT, FRTR
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AUTO_SETUP, ASET
Description
The AUTO_SETUP command attempts to display the input signal(s) by adjusting the vertical, timebase
and trigger parameters. AUTO_SETUP operates only on the channels whose traces are currently turned
on. If no traces are turned on, AUTO_SETUP operates on all channels.
If signals are detected on several channels, the lowest numbered channel with a signal determines the
selection of the timebase and trigger source.
If only one input channel is turned on, the timebase will be adjusted for that channel.
The AUTO_SETUP FIND command adjusts gain and offset only for the specified channel.
Command Syntax
<channel>:AUTO_SETUP [FIND]
<channel>:= <C1 to Cx>
If the FIND keyword is present, gain and offset adjustments are performed only on the specified channel. If
no <channel> prefix is added, an auto-setup is performed on the channel used on the last ASET FIND
remote command.
In the absence of the FIND keyword, the normal auto-setup is performed, regardless of the <channel>
prefix.
Example (GPIB)
The following instructs the oscilloscope to perform an auto-setup:
CMD$="C1:ASET": CALL IBWRT(SCOPE%,CMD$)
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Part 6: IEEE 488.2 Command Reference
ATTENUATION, ATTN
Description
The ATTENUATION command selects the vertical attenuation factor of the probe. Values up to 10000
can be specified.
The ATTENUATION? query returns the attenuation factor of the specified channel.
Command Syntax
<channel>:ATTENUATION <attenuation>
<channel>:= <C1 to Cx, EX, EX10>
<attenuation>:= {1, 2, 5, 10, 20, 25, 50, 100, 200, 500, 1000, 10000}
Query Syntax
<channel>:ATTENUATION?
Response Format
<channel>:ATTENUATION <attenuation>
Example (GPIB)
The following instruction sets the attenuation factor of C1to 100:
CMD$="C1:ATTN 100": CALL IBWRT(SCOPE%,CMD$)
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BANDWIDTH_LIMIT, BWL
Description
The BANDWIDTH_LIMIT command enables or disables the bandwidth-limiting low-pass filter on a per-
channel basis. When the <channel> argument is omitted, the BWL command applies to all channels.
The response to the BANDWIDTH_LIMIT? query shows the bandwidth filter setting for each channel.
Command Syntax
BANDWIDTH_LIMIT [<channel>,]<mode>[,<channel>,<mode>...]
<channel>:= <C1 to Cx>
<mode>:= {OFF, 20MHZ, 200MHZ, 500MHZ, 1GHZ, 2GHZ, 3GHZ, 4GHZ, 6GHZ}
Per channel bandwidth may be set incrementally.
The <mode> setting is limited to the bandwidth filters available on your oscilloscope model. 500MHZ and
2GHZ filters available on HDO9000 models only. More settings are available for WaveMaster and
LabMaster models. See the product datasheet for specifications.
Query Syntax
BANDWIDTH_LIMIT?
Response Format
BANDWIDTH_LIMIT <channel>,<mode>[,<channel>,<mode>...]
Example (GPIB)
The following turns off bandwidth limit filters for all channels:
CMD$="BWL OFF": CALL IBWRT(SCOPE%, CMD$)
The following turns on the 200 MHz bandwidth filter for C1 only:
CMD$="BWL C1,200MHZ": CALL IBWRT(SCOPE%, CMD$)
The following is the response to the BWL? query following the last two commands:
BWL C1,200MHZ,C2,OFF,C3,OFF,C4,OFF
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Part 6: IEEE 488.2 Command Reference
COMBINE_CHANNELS, COMB
Description
The COMBINE_CHANNELS command controls the channel interleaving function of the acquisition system.
The COMBINE_CHANNELS? query returns the channel interleaving function's current status.
Command Syntax
COMBINE_CHANNELS <state>
<state> : = {1, 2, AUTO}
Where 1 = no interleaving; 2 = two interleaved pairs; AUTO = oscilloscope determines based on the active
channels.
Query Syntax
COMBINE_CHANNELS?
Response Format
COMB <state>
Example (GPIB)
The following instruction engages channel interleaving of C1 and C2, and C3 and C4:
CMD$="COMB 2": CALL IBWRT(SCOPE%,CMD$)
The following instruction sets Auto-Combine mode:
CMD$="COMB AUTO": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TDIV
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COUPLING, CPL
Description
The COUPLING command selects the coupling mode of the specified input.
The COUPLING? query returns the coupling mode of the specified channel.
Command Syntax
<channel>:COUPLING <coupling>
<channel>:= <C1 to Cx, EX, EX10, ETM10>
<coupling>:= {A1M, D1M, D50, GND}
The selected coupling value must be one that is available on the oscilloscope. Not all values are supported
by all instruments.
A1M and D1M attenuation pertains only to instruments with a probe connected.
Query Syntax
<channel>:COUPLING?
Response Format
<channel>:COUPLING <coupling>
<coupling>:= {A1M, D1M, D50, GND, OVL}
OVL is returned in the event of signal overload while in DC 50 coupling. In this condition, the oscilloscope
will disconnect the input.
Example (GPIB)
The following instruction sets the coupling of C2 to 50 DC:
CMD$="C2:CPL D50": CALL IBWRT(SCOPE%,CMD$)
The following instruction sets of the coupling of the EXT input to DC 1 Mohm:
CMD$="EX:CPL D1M": CALL IBWRT(SCOPE%,CMD$)
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Part 6: IEEE 488.2 Command Reference
FORCE_TRIGGER, FRTR
Description
Causes the instrument to make one acquisition.
Command Syntax
FORCE_TRIGGER
Example (GPIB)
Either of the following programs forces the oscilloscope to make one acquisition:
CMD$="TRMD SINGLE;ARM;FRTR"
CALL IBWRT(Scope%, CMD$)
CMD$ = "TRMD STOP;ARM;FRTR"
CALL IBWRT(Scope%, CMD$)
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INTERLEAVED, ILVD
Description
The INTERLEAVED command enables or disables random interleaved sampling (RIS) for timebase
settings where both single shot and RIS mode are available.
RIS is not available for sequence mode acquisitions. If sequence mode is on, ILVD ON turns it off.
The response to the INTERLEAVED? query indicates whether the oscilloscope is in RIS mode.
Command Syntax
INTERLEAVED <mode>
<mode>:= {ON, OFF}
Query Syntax
INTERLEAVED?
Response Format
INTERLEAVED <mode>
Example (GPIB)
The following instructs the oscilloscope to use RIS mode:
CMD$="ILVD ON": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TIME_DIV, TRIG_MODE, MEMORY_SIZE, SEQUENCE
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Part 6: IEEE 488.2 Command Reference
MEMORY_SIZE, MSIZ
Description
On most models where this command/query is available, MEMORY_SIZE allows selection of the memory
length used for acquisition. Refer to the product datasheet at teledynelecroy.com for maximum memory
specifications.
The MEMORY_SIZE? query returns the current maximum memory length used to capture waveforms.
Command Syntax
MEMORY_SIZE <size>
<size>:= <500, 1e+3, …, 2.5e+6, 5e+6, 1e+7, etc.>
Or, alternatively:
<size>: = <500, 1000, 2500, 5000, 10K, 25K, 50K, 100K, 250K, 500K, 1MA, 2.5MA, 5MA,
10MA, 25MA, etc.>
Values other than those listed here are recognized by the oscilloscope as numeric data. For example, the
oscilloscope recognizes 1.0M as 1 millisample. However, it recognizes 1MA as 1 megasample.
Note: The oscilloscope adapts to the closest valid memory size according to available channel
memory. Reducing the number of data points results in faster throughput.
Query Syntax
MSIZ?
Response Format
MEMORY_SIZE <size>
Example (GPIB)
The following instruction sets the oscilloscope to acquire at most 10,000 data samples per single-shot or
RIS acquisition:
CMD$="MSIZ 10K": CALL IBWRT(SCOPE%,CMD$)
CMD$="MSIZ 10e+3": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TDIV
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MAUI Oscilloscopes Remote Control and Automation Manual
OFFSET, OFST
Description
The OFFSET command allows adjustment of the vertical offset of the specified input channel at the probe
tip.
Note: The offset takes into the account the attenuation factor (set by command ATTN, default
1.0) and the sensitivity of the probe attached to the channel input, if any.
The maximum ranges depend on the fixed sensitivity setting. Refer to the product datasheet at
teledynelecroy.com for maximum offset specifications.
If an out-of-range value is entered, the oscilloscope is set to the closest possible value and the VAB bit (bit
2) in the STB register is set.
The OFFSET? query returns the DC offset value of the specified channel at the probe tip.
Command Syntax
<channel>:OFFSET <offset>[V]
<channel>:= <C1 to Cx>
<offset>:= <any valid value>
The unit V is optional.
Query Syntax
<channel>:OFFSET?
Response Format
<channel>:OFFSET <offset>
Example (GPIB)
The following instruction sets the offset of C2 to -3 V:
CMD$="C2:OFST -3V": CALL IBWRT(SCOPE%,CMD$)
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Part 6: IEEE 488.2 Command Reference
REFERENCE_CLOCK, RCLK
Description
The REFERENCE_CLOCK command allows for selection of either internal or external reference clock.
Command Syntax
REFERENCE_CLOCK <state>
<state>:= {INTERNAL, EXTERNAL}
Query Syntax
REFERENCE_CLOCK?
Response Format
REFERENCE_CLOCK <state>
Example (GPIB)
The following instruction sets the instrument to use an external reference clock:
CMD$="RCLK EXTERNAL":CALL IBWRT(SCOPE%,CMD$)
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MAUI Oscilloscopes Remote Control and Automation Manual
SAMPLE_CLOCK, SCLK
Description
The SAMPLE_CLOCK command selects for an internal or external sample clock.
Command Syntax
SAMPLE_CLOCK <state>
<state>:= {INTERNAL, EXTERNAL}
Query Syntax
SAMPLE_CLOCK?
Response Format
SAMPLE_CLOCK <state>
Example (GPIB)
The following instruction sets the instrument to use an external sample clock:
CMD$="SCLK EXTERNAL":CALL IBWRT(SCOPE%,CMD$)
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Part 6: IEEE 488.2 Command Reference
SEQUENCE, SEQ
Description
The SEQUENCE command sets the conditions for the sequence mode acquisition. The response to the
SEQUENCE? query gives the conditions for the sequence mode acquisition.
When Sequence mode is turned by using this command, SMART memory is automatically enabled and
the memory length is set to the user-supplied <max_size> value. The argument <max_size> can be
expressed either as numeric fixed point, exponential, or using standard suffixes.
Sequence mode cannot be used at the same time as random interleaved sampling (RIS). If RIS is on, the
command SEQ ON turns RIS off.
Refer to the product datasheet at teledynelecroy.com for Sequence mode specifications.
Command Syntax
SEQUENCE <mode>[,<number segments>[,<max_size>]]
<mode> : = {OFF, ON}
<number segments> : = <any valid value>
<max_size> : = <any valid value, e.g., 10e+3 , 5K, 1M, etc.>
Note: The oscilloscope adapts the requested <max_size> to the closest valid value.
Query Syntax
SEQUENCE?
Response Format
SEQUENCE <mode>,<number segments>,<max_size>
Example (GPIB)
The following instruction sets the segment count to 43, the maximum segment size to 250 samples, and
turns the sequence mode on:
CMD$="SEQ ON,43,250": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TRIG_MODE
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MAUI Oscilloscopes Remote Control and Automation Manual
STOP
Description
The STOP command immediately stops the acquisition of a signal. If the trigger mode is AUTO or NORM,
STOP places the oscilloscope in Stopped trigger mode to prevent further acquisition.
Command Syntax
STOP
Example (GPIB)
The following instruction stops the acquisition process:
CMD$ ="STOP": CALL IBWRT(SCOPE%,CMD$)
Related Commands
ARM_ACQUISITION, TRIG_MODE, WAIT, FORCE_TRIGGER
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Part 6: IEEE 488.2 Command Reference
TIME_DIV, TDIV
Description
The TIME_DIV command modifies the timebase setting. The timebase setting can be specified with units:
NS for nanoseconds, US for microseconds, MS for milliseconds, S for seconds, or KS for kiloseconds.
Alternatively, you can use exponential notation: 10E-6, for example. An out-of-range value causes the VAB
bit (bit 2) in the STB register to be set. Refer to the STB table in the *STB?- *STB? topic for more
information.
The TIME_DIV? query returns the current timebase setting.
Refer to the product datasheet at teledynelecroy.com for timebase specifications.
Command Syntax
TIME_DIV <value>[KS,S,MS,US,NS]
<value>:= <any valid value>
The unit is optional.
Query Syntax
TIME_DIV?
Response Format
TIME_DIV <value>
Example (GPIB)
The following instruction sets the timebase to 500 µs/div:
CMD$="TDIV 500US": CALL IBWRT(SCOPE%,CMD$)
The following instruction sets the timebase to 2 msec/div:
CMD$="TDIV 0.002": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TRIG_DELAY, TRIG_MODE
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MAUI Oscilloscopes Remote Control and Automation Manual
TRIG_COUPLING, TRCP
Description
The TRIG_COUPLING command sets the coupling mode of the specified trigger source.
The TRIG_COUPLING? query returns the trigger coupling of the selected source.
Note: The TRCP command affects only the coupling of the signal path to the trigger circuit,
regardless of input impedance or coupling settings. To set the coupling on the input, use the
COUPLING command.
Command Syntax
<trig_source>:TRIG_COUPLING <trig_coupling>
<trig_source>:= <C1 to Cx, EX, EX10, ETM10>
<trig_coupling>:= {AC, DC, HFREJ, LFREJ}
Query Syntax
<trig_source>:TRIG_COUPLING?
Response Format
<trig_source>:TRIG_COUPLING <trig_coupling>
Example (GPIB)
The following instruction sets the trigger coupling of the trigger source C2 to AC:
CMD$="C2:TRCP AC": CALL IBWRT(SCOPE%,CMD$)
Related Commands
COUPLING, TRIG_DELAY, TRIG_LEVEL, TRIG_MODE, TRIG_SELECT, TRIG_SLOPE
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Part 6: IEEE 488.2 Command Reference
TRIG_DELAY, TRDL
Description
The TRIG_DELAY command sets the time at which the trigger is to occur with respect to the nominal zero
delay position, which defaults to the center of the grid. This is also referred to as Horizontal Delay.
The response to the TRIG_DELAY? query indicates the trigger time with respect to the first acquired data
point. Setting a trigger delay value of zero places the trigger indicator at the center of the grid.
Note: MAUI oscilloscopes support programming the trigger delay in units of time; the legacy
argument PCT (of grid) is no longer supported. Positive values move the trigger position to the
right of the nominal zero delay position, and increase the portion of the waveform before the
trigger point. Negative values move the trigger point in the opposite direction.
Command Syntax
TRIG_DELAY <value>
The <value> is given in time and may be anywhere in the ranges:
Negative delay: ( 0 to -10,000) x Time/div
Postive delay: (0 to +10) x Time/div
If a value outside these ranges is specified, the trigger time is set to the nearest limit and the VAB bit (bit 2)
is set in the STB register.
Query Syntax
TRIG_DELAY?
Response Format
TRIG_DELAY <value>
Example (GPIB)
The following instruction sets a post-trigger delay of -20 S:
CMD$="TRDL -20S": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TIME_DIV, TRIG_COUPLING, TRIG_LEVEL, TRIG_MODE, TRIG_SELECT, TRIG_SLOPE
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MAUI Oscilloscopes Remote Control and Automation Manual
*TRG
Description
The *TRG command executes an ARM command. *TRG is the equivalent of the 488.1 GET (Group
Execute Trigger) message.
Command Syntax
*TRG
Example (GPIB)
The following instruction enables signal acquisition:
CMD$="*TRG": CALL IBWRT(SCOPE%,CMD$)
Related Commands
ARM_ACQUISITION, STOP, WAIT, FORCE_TRIGGER
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Part 6: IEEE 488.2 Command Reference
TRIG_LEVEL, TRLV
Description
The TRIG_LEVEL command adjusts the trigger level of the specified trigger source. An out-of-range value
will be adjusted to the closest legal value and will cause the VAB bit (bit 2) in the STB register to be set.
The TRIG_LEVEL? query returns the current trigger level.
Command Syntax
<trig_source>:TRIG_LEVEL <trig_level>V
<trig_source>:= <C1 to Cx, EX, EX10, ETM10>
The <trig_source> value is optional.
Query Syntax
<trig_source>:TRIG_LEVEL?
Response Format
<trig_source>:TRIG_LEVEL <trig_level>
Example (GPIB)
The following instruction adjusts the trigger level of C2 to -3.4 V:
CMD$="C2:TRLV -3.4V": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TRIG_COUPLING, TRIG_DELAY, TRIG_MODE, TRIG_SELECT, TRIG_SLOPE
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MAUI Oscilloscopes Remote Control and Automation Manual
TRIG_MODE, TRMD
Description
The TRIG_MODE command specifies the trigger mode.
The TRIG_MODE? query returns the current trigger mode.
Command Syntax
TRIG_MODE <mode>
<mode>:= {AUTO, NORM, SINGLE, STOP}
Note: Some older model oscilloscopes force an acquisition by sending the command TRMD
SINGLE with the oscilloscope armed. You can achieve the same effect on current oscilloscope
models by sending the FORCE_TRIGGER command.
Query Syntax
TRIG_MODE?
Response Format
TRIG_MODE <mode>
Example (GPIB)
The following instruction selects the normal mode:
CMD$="TRMD NORM": CALL IBWRT(SCOPE%,CMD$)
Related Commands
ARM_ACQUISITION, FORCE_TRIGGER, STOP, TRIG_SELECT, SEQUENCE, TRIG_COUPLING, TRIG_LEVEL,
TRIG_SLOPE
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Part 6: IEEE 488.2 Command Reference
TRIG_PATTERN, TRPA
Description
The TRIG_PATTERN command defines a trigger pattern. The command specifies the logic level of the
sources C1 to C4 and External, and the states under which logic pattern a trigger can occur. This
command can be used even if the Pattern trigger is not activated.
The TRIG_PATTERN? query returns the current trigger pattern.
Command Syntax
TRIG_PATTERN [<source>,<state>,...<source>,<state>],STATE,<condition>
<source>:= <C1 to Cx, EX>
<state>:= {L, H}
<condition>:= {AND, OR, NAND, NOR}
While optional, at least one source state parameter should be set, otherwise there will be no meaningful
pattern. If a source state is not specified in the command, the source is set to the "X" (Don't Care) state.
Query Syntax
TRIG_PATTERN? [<source>,<state>,...<source>,<state>],STATE,<condition>
Response Format
TRIG_PATTERN [<source>,<state>,...<source>,<state>],STATE,<condition>
The response sends back only L (Low) or H (High) source states and ignores the X states.
Example (GPIB)
The following instruction configures the triggering logic pattern as CH 1 = H, CH 2 = L, CH 3 = X, CH 4 = H
and defines the condition binding them as NOR.
CMD$=“TRPA C1,H,C2,L,C4,H,STATE,NOR”: CALL IBWRT(SCOPE%,CMD$)
Related Commands
TRIG_COUPLING, TRIG_DELAY, TRIG_LEVEL, TRIG_MODE, TRIG_SELECT, TRIG_SLOPE
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MAUI Oscilloscopes Remote Control and Automation Manual
TRIG_SELECT, TRSE
Description
The TRIG_SELECT command selects the conditions that trigger the acquisition of waveforms. Depending
on the trigger type, additional parameters may need to be specified. These additional parameters are
grouped in pairs. The first in the pair names the variable for modification, while the second gives the new
value for assignment. Pairs may be given in any order and restricted only to the variables to be changed.
The oscilloscope interprets the "Hold Type" (HT) parameter as instruction to hold the trigger for a given
amount of time or number of events, or until a certain trigger source or qualifier source condition is
achieved (e.g., a pulse of a given width). The "Hold Value" (HV) parameter provides the value that satisfies
the HT condition; they are always used together.
State Qualified and Edge Qualified triggers should use the Qualifier Source (QL) parameter and include any
HT conditions to be observed on the qualifying signal.
The level used for the Edge and Edge Qualified trigger types is supplied with the TRIG_LEVEL command,
and the slope with the TRIG_SLOPE command. These are not set using the HT parameter.
To set logic pattern triggers, use the Automation commands or the GPIB command TRIG_PATTERN. The
receipt of the TRIG_PATTERN command overrides the TRIG_SELECT settings until another TRIG_SELECT
is sent.
Use the Automation commands to set any trigger not shown here. See the product datasheet for the
triggers supported by your model.
Command Syntax
For all but the TV trigger, the command syntax for standard triggers is:
TRIG_SELECT <trig_type>,SR,<source>[,QL,<source>,HT,<hold_type>,HV,<hold_
value>,HV2,<hold value>]
See table below for valid parameter values.
The trigger sources available depend on your oscilloscope model. See the product datasheet for
specifications.
When specifying <hold_value>, the unit S (seconds) is optional; other units should be specified using the
notation shown in Units and Multipliers.
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Part 6: IEEE 488.2 Command Reference
The following table shows the command notation used to create the parameter-value pairs.
Parameters Mnemonic Values Mnemonic Notes
Trigger Type Dropout DROP
Edge EDGE
Glitch GLIT
Interval INTV
Pattern PA
Runt RUNT
Slew Rate SLEW
State Qualified SQ Add Qualifier Source parameter
Edge Qualified TEQ
Qualified First TEQ1
TV TV Unique syntax, see below
Single-source SNG For backward compatibility with leg-
acy oscilloscopes
Standard STD
Trigger Source SR C1 through CxC1...CxFor best results, use C1 through
C4 only. Use C2 and C3 for DBI
acquisitions.
Auxilliary Line In LINE
External Trigger EX , EX5, EX10,
ETM10
See product datasheet for avail-
able external trigger inputs.
Qualifier Source QL See Trigger Source
Hold Type HT Time greater than TI Holdoff is not available for SNG
and STD triggers.
Time less than TL
Events EV
Pulse larger than PL
Pulse smaller than PS
Pulse width P2 Add HV and HV2
Interval larger than IL
Interval smaller than IS
Interval width I2 Add HV and HV2
No hold-off on wait OFF
First Hold Value HV <value><unit> Holdoff is not available for SNG
and STD triggers.
Second Hold Value HV2 <value><unit>
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MAUI Oscilloscopes Remote Control and Automation Manual
TV Trigger Syntax
TV trigger syntax is:
TRIG_SELECT TV,SR,<source>,FLDC,<field_count>,FLD,<trigger_field>,
CHAR,<characteristics>,LPIC,<lpic>,ILAC,<ilace>,LINE,<trigger_line>
<source>:= <C1 to Cx, LINE, EX, EX5, EX10, ETM10>
<field_count>:= {1, 2, 4, 8}
<trigger_field>:= 1 to field_count
<characteristics>:= {NTSC, PALSEC, CUST50, CUST60}
<lpic>:= 1 to 1500
<ilace>:= {1, 2, 4, 8}
<trigger_line>:= 1 to 1500, or 0 for any line
DDA Trigger Syntax
DDA models and oscilloscopes with the DDA software option installed include the following disk drive
analysis trigger types:
Read Gate Trigger
TRIG_SELECT READ,SR,<read gate source>,WIDTH,<min. read gate pulse width>
Sector Pulse Trigger
TRIG_SELECT SECTOR,SR,<sector source>,QL,<index source>NUM,<sector number>
Servo Gate Trigger
TRIG_SELECT SERVO,SR,<servo gate source>,QL,<index source>,FIRST,<servo burst after
index for first trigger>,SKIP,<skip number of bursts before next trigger>
PES Window Trigger
TRIG_SELECT PESWIN,SR,<PES source>,QL,<servo gate source>,WINDOW,<window size>
See the DDA Reference Manual for more information about the operation of these triggers.
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Part 6: IEEE 488.2 Command Reference
Query Syntax
TRIG_SELECT?
Response Format
TRIG_SELECT <trig_type>,SR,<source>,HT,<hold_type>,HV,<hold_value>
The HV2 value is returned only if <hold_type> is P2 or I2.
Example (GPIB)
The following instruction selects the Single-Source trigger with C1 as trigger source. Hold type condition is
the occurrence of a "pulse smaller than" the hold value of 20 ns:
CMD$="TRSE SNG,SR,C1,HT,PS,HV,20NS": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TRIG_LEVEL, TRIG_SLOPE, TRIG_PATTERN
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MAUI Oscilloscopes Remote Control and Automation Manual
TRIG_SLOPE, TRSL
Description
The TRIG_SLOPE command sets the trigger slope of the selected trigger source.
The TRIG_SLOPE? query returns the trigger slope of the selected source.
Command Syntax
<trig_source>:TRIG_SLOPE <trig_slope>
<trig_source>:= {C1, C2, C3, C4, LINE, EX, EX10, ETM10}
<trig_slope>:= {NEG, POS}
Query Syntax
<trig_source>:TRIG_SLOPE?
Response Format
<trig_source>:TRIG_SLOPE <trig_slope>
Example (GPIB)
The following instruction sets the trigger to the negative slope of C2:
CMD$="C2:TRSL NEG": CALL IBWRT(SCOPE%,CMD$)
Related Commands
TRIG_COUPLING, TRIG_DELAY, TRIG_LEVEL, TRIG_MODE, TRIG_SELECT, TRIG_SLOPE
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Part 6: IEEE 488.2 Command Reference
VOLT_DIV, VDIV
Description
The VOLT_DIV command sets the vertical sensitivity in Volts/div. Refer to the product datasheet at
teledynelecroy.com for a list of valid ranges.
The vertical sensitivity includes the attenuation factor (set by the command ATTN, default 1.0) and the
sensitivity of the probe attached to the channel input, if any.
If an out-of-range value is entered, the VAB bit (bit 2) in the STB register is set. Refer to the STB table in the
*STB? topic for more information.
The VOLT_DIV? query returns the vertical sensitivity of the specified channel at the probe tip.
Command Syntax
<channel>:VOLT_DIV <v_gain>
<channel>:= <C1 to Cx>
<v_gain>:= <any valid value><unit>
When specifying <v_gain>, the unit V is optional. Other units should be specified using the notation in Units
and Multipliers.
Query Syntax
<channel>:VOLT_DIV?
Response Format
<channel>:VOLT_DIV <v_gain>
Example (GPIB)
The following instruction sets the vertical sensitivity of channel 1 to 50 mV/div:
CMD$="C1:VDIV 50MV": CALL IBWRT(SCOPE%,CMD$)
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MAUI Oscilloscopes Remote Control and Automation Manual
WAIT
Description
The WAIT command prevents your instrument from analyzing new commands until the current
acquisition has been completed. The optional argument specifies the timeout (in seconds) after which the
scope stops waiting for new acquisitions. If a timeout value (<t>) is not given, or if <t> = 0.0, the scope
waits indefinitely.
Command Syntax
WAIT [<t>]
<t>:= time in seconds
Example (GPIB)
send: "TRMD SINGLE"
loop {send:"ARM;WAIT;*OPC;C1:PAVA? MAX"
read response
process response
}
This example finds the maximum amplitudes of several signals acquired one after another. ARM starts a
new data acquisition. The WAIT command ensures that the maximum is evaluated for the newly acquired
waveform.
The query "C1:PAVA? MAX" instructs the oscilloscope to evaluate the maximum data value in the Channel
1 waveform.
Related Commands
*TRG, TRIG_MODE, ARM
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Part 6: IEEE 488.2 Command Reference
AUTOMATION Commands and Queries
VBS, VBS
Description
The VBS command allows Automation commands to be sent in the context of an existing program.
The Automation command must be placed within single quotation marks.
The equal sign (=) within the automation command may be flanked by optional spaces for clarity.
Tip: See XStreamBrowser for instructions on accessing the Automation hierarchy.
Command Syntax
VBS '<automation command>'
Query Syntax
VBS? 'Return=<automation command>'
Examples (GPIB)
The following examples show the use of the VBS command to send an automation command over an NI
GPIB interface. The second column shows the equivalent GPIB-only command.
VBS with Embedded Automation Command Equivalent GPIB-only Command
Set C1 vertical scale to 50 mV/div
CMD$="VBS 'app.Acquisition.C1.VerScale=0.05'" CMD$ "C1:VDIV 50 MV"
Set horizontal scale (timebase) to 500 ns/div
CMD$="VBS 'app.Horizontal.HorScale = 500e-9'" CMD$ "TDIV 0.5e-6"
Change grid mode to Dual
CMD$="VBS 'app.Display.GridMode = Dual'" CMD$ "GRID DUAL"
Query the vertical scale of C1
CMD$ = "VBS? 'Return=app.Acquisition.C1.VerScale'" CMD$ "C1:VDIV?"
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MAUI Oscilloscopes Remote Control and Automation Manual
COMMUNICATION Commands and Queries
COMM_FORMAT, CFMT
Description
The COMM_FORMAT command selects the format the oscilloscope uses to send waveform data. The
available options allow the block format, the data type and the encoding mode to be modified from the
default settings.
Initial settings (after power-on) are: block format DEF9; data type WORD; encoding BIN.
The COMM_FORMAT? query returns the currently selected waveform data format.
Command Syntax
COMM_FORMAT <block_format>,<data_type>,<encoding>
<block_format>:= {DEF9, OFF}
<data_type>:= {BYTE, WORD}
<encoding>:= {BIN}
Block Format
The IEEE 488.2 definite length arbitrary block response data format is specified using DEF. The digit 9
indicates that the byte count consists of 9 digits. The data block directly follows the byte count field.
For example, a data block consisting of three data bytes would be sent as:
WF DAT1,#9000000003<DAB><DAB><DAB><NL^END>
<DAB> represents an eight-bit binary data byte.
<NL^END> (new line with EOI) signifies the block transmission has ended.
Note: The block format OFF does not conform to the IEEE 488.2 standard and is only provided for
special applications where the absolute minimum of data transfer may be important.
Data Type
BYTE transmits the waveform data as 8-bit signed integers (one byte).
WORD transmits the waveform data as 16-bit signed integers (two bytes).
Note: The data type BYTE transmits only the high-order bits of the internal 16-bit representation.
The precision contained in the low-order bits is lost.
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Part 6: IEEE 488.2 Command Reference
Encoding
BIN specifies Binary encoding. This is the only type of waveform data encoding supported by Teledyne
LeCroy oscilloscopes.
Query Syntax
COMM_FORMAT?
Response Format
COMM_FORMAT <block_format>,<data_type>,<encoding>
Example (GPIB)
The following instruction redefines the transmission format of waveform data as a block of definite length,
9-digit data count field, data encoded in binary and represented as 8-bit signed integers.
CMD$="CFMT DEF9,BYTE,BIN": CALL IBWRT(SCOPE%,CMD$)
Related Commands
WAVEFORM
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MAUI Oscilloscopes Remote Control and Automation Manual
COMM_HEADER, CHDR
Description
The COMM_HEADER command controls the way the oscilloscope formats responses to queries. There
are three response formats; unless you request otherwise, the short response format is used.
This command does not affect the interpretation of messages sent to the oscilloscope, only responses to
queries. Headers can be sent in long or short form regardless of the COMM_HEADER setting.
Command Syntax
COMM_HEADER <mode>
<mode>:= {SHORT, LONG, OFF}
Format Example Response
LONG Responses start with the long form of the header word C1:VOLT_DIV 200E-3 V
SHORT Responses start with the short form of the header word C1:VDIV 200E-3 V
OFF Headers are omitted from the response and units are suppressed 200E-3
Query Syntax
COMM_HEADER?
Response Format
COMM_HEADER <mode>
Example (GPIB)
The following code sets the response header format to LONG:
CMD$="CHDR LONG": CALL IBWRT(SCOPE%,CMD$)
Related Commands
COMM_HELP_LOG
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Part 6: IEEE 488.2 Command Reference
COMM_HELP_LOG?, CHL?
Description
The COMM_HELP_LOG query returns the current contents of the log generated by the Remote Control
Assistant. If the optional parameter CLR is specified, the log is cleared after the transmission; otherwise,
its kept.
Query Syntax
COMM_HEADER_LOG? [CLR]
Response Format
COMM_HEADER_LOG <string containing the logged text>
Example (GPIB)
The following instruction reads and prints the remote control log:
CMD$="CHL?": CALL IBWRT(SCOPE%,CMD$)PRINT
Related Commands
COMM_HELP
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MAUI Oscilloscopes Remote Control and Automation Manual
COMM_HELP, CHLP
Description
The COMM_HELP command controls the level of operation of the Remote Control Assistant, which assists
in debugging remote control programs. This diagnostics utility is selected on the instrument's Utilities
dialog. Remote Control Assistant can log all message transactions occurring between the external
controller and the oscilloscope (full dialog), or errors only. You can view the log at any time on-screen.
Command Syntax
COMM_HELP <level>,<reset at power on>
<level>:= {OFF, EO, FD}
<reset at power on>:= {NO, YES}
LEVELS OPERATION
OFF Don't assist at all
EO Log detected Errors Only
FD Log the Full Dialog between the controller and the oscilloscope
If <reset at power on> is set to YES, at power-on the logging level is set to EO and the log is cleared. If set to
NO, the user-set logging level is preserved and the log is not cleared.
Setting <reset at power on> to NO is useful when logging command sequences to include rebooting the
oscilloscope.
The default level is EO, and reset at power on is YES.
Query Syntax
COMM_HELP?
Response Format
COMM_HELP<level>,<reset at power on>
Example (GPIB)
After sending this command, all the following commands and responses are logged:
CMD$="CHLP FD": CALL IBWRT(SCOPE%,CMD$)
Related Commands
COMM_HELP_LOG
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Part 6: IEEE 488.2 Command Reference
COMM_ORDER, CORD
Description
The COMM_ORDER command controls the byte order of waveform data transfers. Waveform data can be
sent with the most significant byte (MSB) or the least significant byte (LSB) in the first position. The
default mode is to send the MSB first. COMM_ORDER applies equally to the waveform's descriptor and
time blocks. In the descriptor some values are 16 bits long (word), 32 bits long (long or float), or 64 bits long
(double). In the time block all values are floating values, meaning, 32 bits long. When COMM_ORDER HI is
specified, the MSB is sent first; when COMM_ORDER LO is specified, the LSB is sent first.
The COMM_ORDER ? query returns the byte transmission order in current use.
Command Syntax
COMM_ORDER <mode>
<mode>:= {HI, LO}
Query Syntax
COMM_ORDER?
Response Format
COMM_ORDER <mode>
Example (GPIB)
The order of transmission of waveform data depends on the data type. The following table illustrates the
different possibilities:
Data Type COMMORDER HI COMMORDERLO
Word <MSB><LSB> <LSB><MSB>
Long or Float <MSB><byte2><byte3><LSB> <LSB><byte3><byte2><MSB>
Double <MSB><byte2>...<byte7><LSB> <LSB><byte7>...<byte2><MSB>
Related Commands
WAVEFORM
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MAUI Oscilloscopes Remote Control and Automation Manual
CURSOR Commands and Queries
CURSOR_MEASURE, CRMS
Description
The CURSOR_MEASURE command specifies the type of cursor or parameter measurements to be
displayed and is the main command for displaying parameters and Pass/Fail test results.
The CURSOR_MEASURE? query indicates which cursors or parameter measurements are currently
displayed.
Command Syntax
CURSOR_MEASURE <mode>[,<submode>]
<mode>:= {CUST, FAIL, HABS, HPAR, HREL, OFF, PASS, VABS, VPAR, VREL}
<submode>:= {STAT, ABS, DELTA, SLOPE}
Where:
lCUST[,STAT] shows user-defined (My Measure) parameters.
lFAIL shows measurements failing Pass/Fail test.
lHABS shows Horizontal Absolute cursors.
lHPAR[,STAT] shows Standard Horizontal parameters.
lHREL[,ABS,DELTA,SLOPE] shows Horizontal Relative cursors.
lOFF turns off cursor and parameter display.
lPASS shows measurements passing Pass/Fail test.
lVABS shows Vertical Absolute cursors.
lVPAR[,STAT]shows Standard Vertical parameters.
lVREL[,ABS,DELTA] shows Vertical Relative cursors.
The submode STAT is optional with modes CUST, HPAR, and VPAR. If present, STAT turns on parameter
statistics display. Absence of STAT turns off parameter statistics.
The submodes ABS and DELTA are optional with modes HREL or VREL. If present, ABS reads absolute
position of relative cursors, whereas DELTA reads the delta of the two cursors. Absence of keyword
selects the DELTA.
The modes PARAM, SHOW DASH, and LIST used with some legacy LeCroy instruments are not available
on XStream instruments.
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Query Syntax
CURSOR_MEASURE?
Response Format
CURSOR_MEASURE <mode>
Example (GPIB)
The following instruction switches on the Vertical relative cursors:
CMD$="CRMS VREL": CALL IBWRT(SCOPE%,CMD$)
The following instruction determines which cursor is currently turned on:
CMDS$=“CRMS?”: CALL IBWRT(SCOPE%,CMD$): CALL IBRD(SCOPE%,RD$): PRINT RD$
Example response message:
CRMS OFF
Related Commands
CURSOR_SET, PARAMETER_STATISTICS, PARAMETER_VALUE, CURSORS, PARAMETER, PASS_FAIL
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CURSORS, CRS
Description
Sets the type of cursor to be used and the readout. Unlike CRMS, this command does not change the
state of parameters or pass/fail.
Command Syntax
CURSORS <type>[,<readout>]
<type>:= {OFF, HREL, HABS, VREL, VABS}
<readout>:= {ABS, SLOPE, DELTA}
The SLOPE argument is used with the Horizontal Relative (HREL) cursor only.
Query Syntax
CURSORS? or CRS?
Example (GPIB)
The following instruction sets the cursors to horizontal relative, and readout to the difference between
them.
CMD$="CRS HREL,DELTA": CALL IBWRT(SCOPE%,CMD$)
Related Commands
CURSOR_MEASURE
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CURSOR_SET, CRST
Description
The CURSOR_SET command allows you to position any one of the independent cursors at a given grid
location.
When setting a cursor position, you must specify the trace on which the cursor is positioned. This means
the trace must be turned on, a requirement not applicable to all legacy LeCroy instruments.
The legacy commands PREF and PDIF are not supported on XStream instruments.
The CURSOR_SET? query indicates the current position of the cursor(s). The values returned depend on
the type selected.
Command Syntax
<trace>:CURSOR_SET <cursor>,<position>[. . .,<cursor>,<position>]
<trace>:= C1 to Cx, F1 to Fx, M1 to Mx, TA, TB, TC, TD
<cursor>:= {HABS, HREF, HDIF, VABS, VREF, VDIF}
<position>:= 0 to 10 DIV horizontal or -3.99 to 3.99 DIV vertical
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
Parameters are grouped in pairs. The first parameter specifies the cursor to be modified and the second
one indicates its new value. Parameter pairings can be listed in any order and restricted to those items to
be changed.
Cursor types are:
lHABS - Horizontal Absolute cursor
lHREF - Reference cursor of Horizontal Relative cursor pair
lHDIF - Difference cursor of Horizontal Relative cursor pair
lVABS - Vertical Absolute cursor
lVREF - Reference cursor of Vertical Relative cursor pair
lVDIF - Difference cursor of Vertical Relative cursor pair
The unit DIV is optional when specifying the position.
Tip: You can change the trace on which cursors are placed without repositioning the cursors by
using the CURSOR_SET command with no arguments (for example, F2:CRST).
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Query Syntax
CURSOR_SET? [<cursor>]
<cursor>:= {HABS, HREF, HDIF, VABS, VREF, VDIF, ALL}
Response Format
<trace>:CURSOR_SET <cursor>,<position>[...,<cursor>,<position>]
If <cursor> is not specified, ALL will be assumed. If the position of a cursor cannot be determined in a
particular situation, its position will be indicated as UNDEF.
Example (GPIB)
The following instruction positions the VREF and VDIF cursors at +3 DIV and -2 DIV respectively on trace
F1:
CMD$="F1:CRST VREF,3DIV,VDIF,-2DIV" :CALL IBWRT(SCOPE%,CMD$)
Related Commands
CURSOR_MEASURE, CURSOR VALUE, PARAMETER_VALUE
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CURSOR_VALUE?, CRVA?
Description
The CURSOR_VALUE? query returns the values measured by the specified cursors for a given trace.
There are important differences in the function of this query between XStream instruments and legacy
LeCroy instruments:
lThe keyword ALL should not be used; neither should multiple keywords. If they are used, the word
UNDEF is returned.
lThe specified trace must be visible (turned on), and the cursor mode currently set on that trace
must be the same as in the query. If it is not the same, UNDEF is returned.
Tip: Use the PARAMETER_VALUE? query to obtain measurement parameter values.
Query Syntax
<trace>:CURSOR_VALUE? [<mode>]
<trace>:= C1 to Cx, F1 to Fx, M1 to Mx, TA to TD
<mode>:= {HABS, HREL, VABS, VREL}
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
Cursor modes are:
lHABS - Horizontal Absolute cursor
lHREL - Horizontal Relative cursors
lVABS - Vertical Absolute cursor
lVREL - Vertical Relative cursors
Response Format
<trace>:CURSOR_VALUE HABS,<abs_hor>
<trace>:CURSOR_VALUE HREL,<delta_hor>,<abs hor_ref>,<abs hor_dif>,<slope>
<trace>:CURSOR_VALUE VABS,<abs_vert>
<trace>:CURSOR_VALUE VREL,<delta_vert>,<abs vert_ref>,<abs vert_dif>
Note: The dV/dt value <slope> is displayed in the appropriate trace descriptor box.
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For horizontal cursors, both horizontal and vertical values are given. For vertical cursors only vertical
values are given.
Example (GPIB)
The following query reads the measured value of the Horizontal Absolute cursor (HABS) on Channel 2:
CMD$=“C2:CRVA? HABS”: CALL IBWRT(SCOPE%,CMD$)
Response message:
C2:CRVA HABS,34.2E-6 S,244 E-3 V
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OFFSET_CONSTANT, OFCT
Description
As you change the gain, this command allows for keeping the vertical offset level indicator stationary
(when DIV is selected) or to have it move with the actual voltage level (when VOLTS is selected). The
advantage of selecting DIV is that the waveform remains on the grid as the gain is increased; whereas,
with VOLTS selected, the waveform could move off the grid.
Regardless of which is selected, the Offset value shown on the oscilloscope Channel setup dialog is always
given in volts. However, DIV is selected for the Offset Control, the offset in volts is scaled proportional to
the change in gain, thereby keeping the grid placement constant.
Command Syntax
OFFSET_CONSTANT <constant>
<constant>:= {VOLTS, DIV}
Query Syntax
OFCT?
Response Format
OFCT VOLTS
Example (GPIB)
CMD$ = "OFCT VOLTS": CALL IBWRT(SCOPE%, CMD$)
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PARAMETER_CLR, PACL
Description
The PARAMETER_CLR command clears all the current parameters in the user-defined (My Measure) and
Pass/Fail sets.
Command Syntax
PARAMETER_CLEAR
Related Commands
PARAMETER_DELETE, PARAMETER_VALUE
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PARAMETER_CUSTOM, PACU
Description
The PARAMETER_CUSTOM command configures user-defined parameters (My Measure) in locations P1
through Px.
Tip: Use PAVA? to read the measured value of a parameter that was set up with PACU. The best
way to learn the required command syntax is to set up the measurement as desired on the
oscilloscope and run the Px: PACU? query. The response will be formatted exactly as required,
especially if you have set the oscilloscope to suppress command headers using COMM_HEADER.
Command Syntax
PARAMETER_CUSTOM <parameter>,<measurement>,<qualifier>[,<qualifier>,...]
<parameter>:= 1 to x, CUST1 to CUST8
<measurement>:= mnemonic from table below or listed by the PAVA? query
<qualifier>:= qualifier(s) for each parameter shown in the tables below
Note: xrepresents the highest number parameter slot on your instrument. CUST1 through CUST8
are included for backward compatibility; they are accepted but not returned by queries.
Query Syntax
PACU? <parameter>
Response Format
PACU <parameter>,<measurement>,<qualifier>[,<qualifier>,...]
Related Commands
PARAMETER_DELETE, PARAMETER_VALUE
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Measurements
Note: Measurements listed here may not be available on all instruments. If you do not already
have access to the measurement on the oscilloscope (Measure Setup selector), you will not have
it via remote control. See the product datasheet at teledynelecroy.com for a list of available
measurements.
Qualifiers shown in the tables below may take the following values and units. Notate the units as shown (V,
PCT, DIV, HZ, etc.).
<source>:= Header Paths and Sources. For histogram measurements, use histogram function Fx.
<level>:= value PCT or V
<slope>:= {POS, NEG}
<hysteresis>:= 0.01 to 8 DIV
<frequency>:= 10 to 1e9 HZ (Narrow Band center frequency)
<signaltype>:= {CLOCK, DATA}
<outputin>:= {TIME, UI}
<referencetype>:= {STANDARD, CUSTOM}
All MAUI Oscilloscopes
These measurements are standard on all MAUI oscilloscopes running XStream v. 8.0.0 or higher.
Measurement Mnemonic Qualifiers
Amplitude AMPL <source>
Area AREA <source>
Base BASE <source>
Delay DLY <source>
Duty cycle DUTY <source>
Fall time 90% to 10% FALL <source>
Fall time 80% to 20% FALL82 <source>
Frequency FREQ <source>
Maximum value MAX <source>
Mean value MEAN <source>
Minimum value MIN <source>
None/cleared NULL <source>
Overshoot negative OVSN <source>
Overshoot positive OVSP <source>
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Measurement Mnemonic Qualifiers
Peak to peak PKPK <source>
Period PER <source>
Phase difference PHASE <source>
Rise time 10% to 90% RISE <source>
Rise time 20% to 80% RISE28 <source>
Root mean square RMS <source>
Time clock to clock edge SKEW <clocksource1>,<clockslope1>,<clocklevel1 PCT | V>,
<clocksource2>,<clockslope2>,<clocklevel2 PCT | V>,
<clockhysteresis1>,<clockhysteresis2>
Standard deviation SDEV <source>
Top TOP <source>
Width 50% positive slope WID <source>
Width 50% negative slope WIDN <source>
HDO4000 and Higher Bandwidth Oscilloscopes
These measurements are standard on HDO4000 and higher, MDA, WaveRunner 8000, WaveRunner/HRO
6 Zi, DDA/SDA/WavePro 7 Zi, DDA/SDA/WaveMaster 8 Zi, and LabMaster series oscilloscopes running
XStream v. 8.0.0 or higher.
Measurement Mnemonic Qualifiers
Delta period @ level DPLEV <signaltype>,<slope>,<level PCT | V>,<hysteresis DIV>,
<referencetype>,<-3dBfrequency HZ>,<frequency HZ>
Delta time @ level DTLEV <source1>,<slope1>,<level1 PCT | V>,<hysteresis1 DIV>
<source2>,<slope2>,<level2 PCT | V>,<hysteresis2 DIV>
Duty cycle @ level DULEV <source>
Edge @ level EDLEV <source>,<slope>,<level PCT | level V>,<hysteresis DIV>
Frequency @ level FREQLEV <signaltype>,<slope>,<level PCT | V>,<hysteresis DIV>,
<referencetype>,<-3dBfrequency HZ>,<frequency HZ>
Period @ level PLEV <signaltype>,<slope>,<level PCT | V>,<hysteresis DIV>,<refer-
encetype>,<-3dBfrequency HZ>,<frequency HZ>
Time @ level TLEV <source>,<slope>,<level PCT | V>,<hysteresis DIV>
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HDO6000 and Higher Bandwidth Oscilloscopes
These measurements are standard on HDO6000 and higher, MDA, WaveRunner 8000, WaveRunner/HRO
6 Zi, DDA/SDA/WavePro 7 Zi, DDA/SDA/WaveMaster 8 Zi, and LabMaster series oscilloscopes running
XStream v. 8.0.0 or higher.
Measurement Mnemonic Qualifiers
Histogram Mean AVG <source>
Math on Parameters CALCx <measure1>,<source1>,<operator>,<measure2>,<source2>
<operator>:= {ADD, SUB, MUL, DIV}
Cycles on screen CYCL <source>
Delta delay DDLY <source>
Delta trigger time DTRIG <source>
Delta width @ level DWIDLEV <source>,<slope>,<level PCT | level V>,<hysteresis DIV>
Duration of acquisition DUR <source>
Excel parameter EXCELPARAM <source1var>,<source2var>,<outputvar>,<source1headervar>,
<source2headervar>,<outputheadervar>,<withheader>,
<outputenable>,<source1enable>,<source2enable>,
<newsheet>,<advanced>,'<worksheetfilename>'
Fall @ level FLEV <source>,<highlevel PCT | V>,<lowlevel PCT | V>
First (left-most) sample in
measure gate
FRST <source>
Histogram FWHM FWHM <source>
Histogram peak FW @ level FWxx <source>,<%maxpopulation PCT>
<%maxpopulation>:= value PCT of max population at which to
measure Full-Width
Half Period HPER <source>,<slope>,<level PCT | V>,<hysteresis DIV>
Histogram amplitude HAMPL <source>
Histogram base level HBASE <source>
Histogram right bin; same
as Histogram maximum
HIGH <source>
Histogram mean HMEAN <source>
Histogram median HMEDI <source>
Time clock edge to data
edge at level
HOLDLEV /
HOLDTIME
<clocksource>,<clockslope>,<clocklevel PCT | V>,
<datasource>,<dataslope>datalevel PCT | V>,
<clockhysteresis DIV>,<datahysteresis DIV>
Histogram rms HRMS <source>
Histogram top level HTOP <source>
Last (right-most) sample in
measure gate
LAST <source>
Histogram left bin; same as
Histogram minimum.
LOW <source>
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Part 6: IEEE 488.2 Command Reference
Measurement Mnemonic Qualifiers
Mathcad parameter MATHCADPARAMARITH <source>,'<function>'
MATLAB parameter MATLABPARAM <source>,'<function>'
Histogram maximum
population
MAXP <source>
Median MEDI <source>
Histogram mode MODE <source>
Narrow Band phase NBPH <source><frequency HZ>
Narrow Band power NBPW <source><frequency HZ>
N cycle jitter NCYCLE <source>
VBS script parameter PARAMSCRIPT <source>,'<code>'
Histogram percentile PCTL <source>
Number of peaks PKS <source>
Number of points PNTS <source>
Population of histogram bin
at x
POPATX <source>,<cursorposition V>
<cursorposition>:= value V representing histogram bin at which
to measure population
Histogram range RANGE <source>
Rise time @ level RLEV <source>,<lowlevel PCT | V>,<highlevel PCT | V>
Data edge to clock edge SETUP <clocksource>,<clockslope>,<clocklevel PCT | V>,
<datasource>,<dataslope>datalevel PCT | V>,
<clockhysteresis DIV>,<datahysteresis DIV>
Histogram standard
deviation
SIGMA <source>
Time Interval Error @ level TIELEV <signaltype>,<slope>,<level PCT | V>,<outputin>,<hysteresis
DIV>,<referencetype>,<-3db@frequency HZ>,<frequency HZ>
Histogram total population TOTP <source>
Width @ level WIDLV <source>,<slope>,<level PCT | V>,<hysteresis DIV>
Pos of max. data value XMAX <source>
Pos of min. data value XMIN <source>
Histogram Nth highest peak XAPK <source>
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XMath/SDA Option Measurements
These measurements are included on SDA 7 Zi and SDA 8 Zi series oscilloscopes running XStream
v. 8.0.0 or higher, or become available with the installation of an XMath or SDA option.
Note: In these cases, you will only be able to set the measurement and source using the PACU
command. Other qualifiers must be set manually or using Automation. Select an Eye Diagram as
the source for eye measurements.
Measurement Mnemonic Qualifiers
Edge displacement EDGEDA <source>
Pattern time PATTERNTIME <source>
Ring back high/low RING <source>
Lane-to-lane skew SD2SKEW <source>
Strip DDj from source STRIPDDJ <source>
Eye diagram zero level ZEROLVL <source>
SDA Option Measurements
These measurements are included on SDA 7 Zi and SDA 8 Zi series oscilloscopes running XStream
v. 8.0.0 or higher, or become available with the installation of an SDA option. As with the measurements in
the table above, you may not be able to set all necessary qualifiers using the PACU command.
Measurement Mnemonic Qualifiers
Eye AC rms EYEACRMS <source>
Eye power level ratio EXTRATIO <source>
Eye amplitude EYEAMPL <source>
Eye bit error rate estimate EYEBER <source>
Eye bit rate EYEBITRATE <source>
Eye bit time EYEBITTIME <source>
Eye crossing EYECROSSING <source>
Eye negative crossing EYECROSSN <source>
Eye positive crossing EYECROSSP <source>
Eye cyc area EYECYCAREA <source>
Eye delay EYEDELAY <source>
Eye delta delay EYEDELTDLY <source>
Eye fall time EYEFALLTIME <source>
Eye height EYEHEIGHT <source>
Eye mean EYEMEAN <source>
Eye one level EYEONE <source>
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Measurement Mnemonic Qualifiers
Eye opening factor EYEOPENFAC <source>
Eye negative overshoot EYEOVERN <source>
Eye positive overshoot EYEOVERP <source>
Eye peak noise EYEPKNOISE <source>
Eye peak-to-peak jitter EYEPKPKJIT <source>
Eye pulse width EYEPULSEWID <source>
Eye Q factor EYEQ <source>
Eye rise time EYERISETIME <source>
Eye RMS jitter EYERMSJIT <source>
Eye std. deviation noise EYESDNOISE <source>
Eye signal to noise EYESGTONOISE <source>
Eye suppression ratio EYESUPRATIO <source>
Eye width EYEWIDTH <source>
Jitter per duty-cycle
distortion
PERDCD <source>
Persistence duty-cycle PERDUTYCYC <source>
Per pulse symmetry PERPULSESYM <source>
PCIe misc. measurements PCIEMISC <source>
Note: This measurement will need additional setup to return any-
thing but the default min. pulse time measurement.
PCIe min. pulse width TMNPLS <source>
PCIe uncorrelated pulse
width DJ
UPWJDD <source>
PCIe uncorrelated pulse
width TJ
UPWTJ <source>
All Other Options
For a description of other measurements made available by option key that may be settable using legacy
remote commands, download the software option manual from our website (see Resources).
The best test of compatibility is to set up the measurement as desired on the oscilloscope, then run the
PACU? query on that parameter. Whatever qualifiers are returned by the PACU? query are what can be set
using the PACU command. These may not be sufficient to fully configure the measurement. Use
Automation with the VBS command to set missing qualifiers.
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PARAMETER_DELETE, PADL
Description
The PARAMETER_DELETE command deletes a parameter/qualifier from the table of results shown for
custom measurements or Pass/Fail testing.
Command Syntax
PARAMETER_DELETE <column>
<column>:= 1 through x
xrepresents the highest number parameter slot on your instrument.
Example (GPIB)
The following instruction deletes the third parameter in the set:
CMD$="PADL 3": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PARAMETER_CLR, PARAMETER_VALUE
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PARAMETER, PARM
Description
This command turns statistics and histicons on or off.
Unlike CRMS, the PARM command does not change the state of cursors or pass/fail.
Command Syntax
PARM <type>,[readout]
Type:= {CUST, HPAR, VPAR, OFF}
Readout:= {STAT, HISTICON, BOTH, OFF}
Without argument, the state of histograms and statistics is unchanged.
Query Syntax
PARAMETER? or PARM?
Response Format
PARM <type>,<readout>
Example (GPIB)
The following instruction turns on histicons:
CMD$="PARM CUST,HISTICON";CALL IBWRT(SCOPE%,CMD$)
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PARAMETER_STATISTICS?, PAST?
Description
The PARAMETER_STATISTICS? query returns all current measurement statistics for the specified
parameter set. By using the optional <statistic> and <param> arguments, the query returns either the
single specified statistic for all measurements in the parameter set, or all statistics for the single specified
parameter.
Query Syntax
PARAMETER_STATISTICS? <mode>[,<statistic>][,<param>]
<mode>:= {CUST, HPAR, VPAR}
<statistic>:= {AVG, LOW, HIGH, SIGMA, SWEEPS, LAST, PARAM}
<param>:= P1 to Px
The <mode> must correspond to the currently configured mode on the oscilloscope. Use:
lCUST when the measure mode is set to My Measure
lVPAR when set to Std Vertical
lHPAR when set to Std Horizontal
If the <mode> does not match the one set on the oscilloscope, the query returns UNDEF.
If the <statistics> keyword PARAM is specified when in CUST mode, the query returns the list of the
<parameter_name>,<source> pairs configured in the custom set, along with the statistical values.
Note: The <statistics> and <param> arguments should not be used together.
Mnemonics
CUST Custom parameters. Use when measure mode is My Measure.
HPAR Horizontal standard parameters. Use when measure mode is Std Horizontal.
VPAR Vertical standard parameters. Use when measure mode is Std Vertical.
AVG Average value (mean row in statistics table)
HIGH highest value (max row in statistics table)
LOW lowest value (min row in statistics table)
PARAM parameter definition for each line
SIGMA sigma (standard deviation)
SWEEPS number of measurements accumulated for each line
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Example A (GPIB)
The following instruction reads the average values for all custom parameters:
CMD$ = "PAST? CUST,AVG" CALL IBWRT (SCOPE%,CMD$) CALL IBRD(SCOPE%,RD$)
The oscilloscope responds with:
PAST CUST,AVG,290.718E-3 V,389.25E-12 V.S,-144.589E-3 V,93.76604E-9 S,
290.725E-3 V,389.25E-12 V.S,-144.589E-3 V,229E-9 V
Example B (GPIB)
The following instruction reads all statistical values for parameter P2:
CMD$ = "PAST? CUST,P2" CALL IBWRT (SCOPE%,CMD$) CALL IBRD(SCOPE%,RD$)
The oscilloscope responds with:
PAST CUST,P1,AMPL,C1,AVG,290.718E-3 V,HIGH,297.5E-3 V,LAST,294.2E-3 V,
LOW,278.2E-3 V,SIGMA,3.047E-3 V,SWEEPS,182
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PARAMETER_VALUE?, PAVA?
Description
The PARAMETER_VALUE query returns the current values of the waveform parameters for the specified
trace. Traces do not need to be displayed to obtain the values reported by PAVA?.
Query Syntax
To query measurement parameters:
<trace>:PAVA? [<parameter>...,<parameter>]
<parameter>:= any standard or user-defined parameter set with PACU
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
Response Format
<trace>:PAVA? <parameter>,<value>,<state>
Note: If <parameter> is not specified, or is equal to ALL, all standard voltage and time parameters
are returned followed by their values and states.
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In addition to the standard and user-defined parameter values, the following states may be returned:
State Description
AV Averaged over several periods
GT Greater than given value
IV Invalid value (insufficient data provided)
LT less than given value
NP No pulse waveform
OF Signal partially in overflow
OK Deemed to be determined without problem
OU Signal partially in overflow and underflow
PT Window has been period truncated
UF Signal partially in underflow
Example (GPIB)
The following instruction reads the rise time of trace C1:
CMD$="C1:PAVA? RISE": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD (SCOPE%,RD$): PRINT RD$
Response message:
RISE,3.6E-9S,OK
Related Commands
CURSOR_MEASURE, CURSOR_SET, PARAMETER_CUSTOM, PARAMETER_STATISTICS
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PER_CURSOR_SET, PECS
Description
The PER_CURSOR_SET command allows you to position one or more of the six independent cursors at a
given grid location. Cursors must be turned on for the PECS command or query to work.
Command Syntax
<trace>:PER_CURSOR_SET <cursor>,<position>[…,<cursor>,<position>]
<trace>:= C1 to Cx, F1 to Fx, M1 to Mx, TA to TD
<cursor>:= {HABS, HDIF, HREF, VABS, VDIF, VREF}
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
xREF and xDIF are the left and right cursors in a relative cursor pair (HREL or VREL). The readout will show
the absolute position of each and the delta between them.
Query Syntaxj
<trace>:PER_CURSOR_SET?
Example (GPIB)
The following instruction positions the HREF and HDIF cursors at +2.6 DIV and +7.4 DIV respectively on the
C2 trace:
CMD$="C2:PECS HREF,2.6 DIV,HDIF,7.4 DIV" CALL IBWRT(SCOPE%,CMD$)
Related Commands
CURSOR_MEASURE, CURSOR_SET, PER_CURSOR_VALUE
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PASS_FAIL, PF
Description
The PASS_FAIL command sets up the Pass/Fail test system.
The PASS_FAIL? query returns the Pass/Fail setup.
Command Syntax
PASS_FAIL <state>,<logic>[,<stop after>]
<state>:= {ON, OFF}
<logic>:= {AllTrue, AllFalse, AnyTrue, AnyFalse, AllQ1ToQ4, AllQ5ToQ8, AllQ9ToQ12,
AnyQ1ToQ4, AnyQ5ToQ8, AnyQ9TOQ12}
<stop after>:= 1 to 1,000,000,000 sweeps
The <logic> argument specifies which set of conditions must be satisfied to constitute a "pass."
Note: The logic accepted by this command depends on the Pass/Fail functionality available on
your instrument. WaveSurfer and HDO4000 oscilloscopes that do not allow you to define
individual PF qualifier conditions do not support the arguments AllQxToQyand AnyQxToQy.These
instruments only support the logic AllTrue.
Query Syntax
PASS_FAIL?
Example (GPIB)
The following instruction sets the test to pass only if all qualifier conditions are false, and to stop after 20
acquisitions:
CMD$="PF ON,ALLFALSE,20": CALL IBWRT(SCOPE%,CMD$)
Related Commands
CRMS
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PASS_FAIL_DO, PFDO
Description
The PASS_FAIL_DO command defines the actions to be performed in the event of the specified outcome
of a Pass/Fail test.
The PASS_FAIL_DO? query indicates which actions are currently selected. If none, no parameters are
returned.
Command Syntax
Pass_Fail_DO <outcome>,<act>[,<act> …]
<outcome>:= {PASS, FAIL}
<act>:= {ALARM, BEEP, PRINT, SCDP, PULSE, PULS, SAVE, STO, STOP}
Where:
ALARM or BEEP = sound a beep.
PRINT or SCDP = send to printer.
PULSE or PULS = emit a pulse from the Aux Out connector.
SAVE or STO = store in currently selected mass storage.
STOP = stop acquisition.
Note: BEEP, SCDP, PULS and STO are provided for backward compatibility. Only the new formats
are returned in queries.
Query Syntax
Pass_Fail_DO?
Response Format
Pass_Fail_DO [<pass_fail>,<act>[,<act> …]]
Example (GPIB)
The following instruction forces the instrument to stop acquiring when the test passes:
CMD$="PFDO PASS,STOP" CALL IBWRT(SCOPE%,CMD$)
Related Commands
BUZZER, CURSOR_MEASURE, CURSOR_SET, INR, PARAMETER_VALUE, PASS_FAIL_MASK
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DISPLAY Commands and Queries
DISPLAY, DISP
Description
The DISPLAY command controls the display screen of the oscilloscope. When remotely controlling the
oscilloscope, and if you do not need to use the display, it can be useful to switch off the display via the
DISPLAY OFF command. This improves oscilloscope response time, since the waveform graphic
generation procedure is suppressed.
In addition, when the oscilloscope is in the DISPLAY OFF mode, certain LEDs and the periodic backup of
the oscilloscope settings are disabled to avoid unnecessary interruptions.
The response to the DISPLAY? query indicates the display state of the oscilloscope.
Note: When you set the display to OFF, the screen does not actually go blank. Instead, the real-
time clock and the message field are continuously updated. but waveforms and associated text
are frozen.
Command Syntax
DISPLAY <state>
<state>:= ON or OFF
Query Syntax
DISPLAY?
Response Format
DISPLAY <state>
Example (GPIB)
The following instruction turns off the display:
CMD$="DISP OFF": CALL IBWRT(SCOPE%,CMD$)
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DOT_JOIN, DTJN
Description
The DOT_JOIN command controls the interpolation lines between data points. Setting DOT_JOIN ON
selects a continuous Line; DOT_JOIN OFF selects a series of Points.
Command Syntax
DOT_JOIN <state>
<state>:= {ON, OFF}
Query Syntax
DOT_JOIN?
Response Format
DOT_JOIN <state>
Example (GPIB)
The following instruction turns off the interpolation lines:
CMD$="DTJN OFF": CALL IBWRT(SCOPE%,CMD$)
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GRID
Description
The GRID command defines the style of the grid used in the display.
The GRID? query returns the grid style currently in use.
The grid value must correspond to a grid style available on your oscilloscope. See your product datasheet,
XStreamBrowser, or the oscilloscope Display Setup dialog for options.
Command Syntax
GRID <grid>
<grid>:= {AUTO, SINGLE, DUAL, QUAD, OCTAL, XY, XYSINGLE, XYDUAL, TANDEM, QUATTRO,
TWELVE, SIXTEEN, TRIPLE, HEX}
Query Syntax
GRID?
Response Format
GRID <grid>
Example (GPIB)
The following instruction sets the screen display to dual grid mode:
CMD$="GRID DUAL": CALL IBWRT(SCOPE%,CMD$)
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HOR_MAGNIFY, HMAG
Description
The HOR_MAGNIFY command horizontally expands a zoom math function trace (a.k.a., expansion trace)
by the specified factor. Magnification factors not within the range of permissible values will be rounded off
to the nearest legal value.
The VAB bit (bit 2) in the STB register table is set when a factor outside the legal range is specified.
The HOR_MAGNIFY? query returns the current magnification factor for the specified expansion function.
Command Syntax
<trace>:HOR_MAGNIFY <factor>
<trace>:= F1 to Fx, TA to TD
<factor>: = 1 to 20000
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
Query Syntax
<exp_source>:HOR_MAGNIFY?
Response Format
<exp_source>:HOR_MAGNIFY <factor>
Example (GPIB)
The following instruction horizontally magnifies trace F1 by a factor of 5:
CMD$="F1:HMAG 5": CALL IBWRT(SCOPE%,CMD$)
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HOR_POSITION, HPOS
Description
The HOR_POSITION command horizontally positions the geometric center of the intensified (zoomed)
zone represented by a zoom math function trace. Allowed positions range from division 0 through 10. If
the source trace was acquired in sequence mode, horizontal shifting will only apply to a single segment at
a time.
If multi-zoom is enabled, the difference in horizontal position (or segment viewed for sequence mode
acquisitions) is applied to all zoom traces. The VAB bit (bit 2) in the STB register table is set if a value
outside the legal range is specified.
The HOR_POSITION? query returns the position of the geometric center of the intensified zone.
Command Syntax
<trace>:HOR_POSITION <hor_position>,<segment>
<trace>:= F1 to Fx, M1 to Mx, TA to TD
<hor_position>:= 0 to 10 [DIV]
<segment>:= 0 to max segments
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
The segment number is only relevant for waveforms acquired in sequence mode; it is ignored in single
waveform acquisitions. When segment number is 0, all segments are shown at default magnification.
Query Syntax
<trace>:HOR_POSITION?
Response Format
<trace>:HOR_POSITION <hor_position | segment>
Note: The segment number is only returned for sequence waveforms.
Example (GPIB)
The following instruction positions the center of the intensified zone on trace F1 at division 3:
CMD$="F1:HPOS 3": CALL IBWRT(SCOPE%,CMD$)
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INTENSITY, INTS
Description
The INTENSITY command sets the intensity level of the grid. The argument "TRACE,<value>" is accepted
for backward compatibility, but the actual trace intensity is always 100%.
Command Syntax
INTENSITY GRID,<value>,TRACE,<value>
Query Syntax
INTENSITY?
Response Format
INTENSITY TRACE,<value>,GRID,<value>
Example (GPIB)
The following example sets the grid intensity to 70%.
CMD$="INTS GRID,70" : CALL IBWRT(SCOPE%,CMD$)
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MESSAGE, MSG
Description
The MESSAGE command displays a string of characters in the message field at the bottom of the
instrument screen.
Command Syntax
MESSAGE "<string>"
<string>:= up to 49 characters
Longer strings are truncated to 49 characters, but the original string is retained and returned by the MSG?
Query. The quotation mark delimiters are required.
Query Syntax
MESSAGE?
Response Format
MESSAGE "<string>"
Example (GPIB)
The following command causes the message 'Touch Probe 2 to Test Point 7' to appear in the oscilloscope
message bar.
CMD$=MSG "'Touch Probe 2 to Test Point 7'": CALL IBWRT(SCOPE%, CMD$)
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PERSIST_COLOR, PECL
Description
The PERSIST_COLOR command controls the color rendering method of persistence traces: ANALOG,
COLOR_GRADED, or 3D. Refer to the datasheet specification for your instrument for availability.
The response to the PERSIST_COLOR? query indicates the color rendering method in use.
Command Syntax
PERSIST_COLOR <state>
<state> : = {ANALOG, COLOR_GRADED, 3D}
Query Syntax
PERSIST_COLOR?
Response Format
PERSIST_COLOR <state>
Example (GPIB)
The following instruction sets the persistence trace color to an intensity-graded range of the selected
trace color:
CMD$="PECL ANALOG": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PERSIST, PERSIST_LAST, PERSIST_SAT, PERSIST_SETUP
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Part 6: IEEE 488.2 Command Reference
PERSIST_LAST, PELT
Description
The PERSIST_LAST command controls whether or not the last trace drawn in a persistence data map is
shown. This command marks or un-marks the "Show Last Trace" checkbox on the Persistence dialog.
Command Syntax
PERSIST_LAST <state>
<state>:= {ON, OFF}
Query Syntax
PERSIST_LAST?
Response Format
PERSIST_LAST <state>
Example (GPIB)
The following instruction ensures the last trace is visible within its persistence data map:
CMD$="PELT ON": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PERSIST, PERSIST_COLOR, PERSIST_SAT, PERSIST_SETUP
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PERSIST, PERS
Description
The PERSIST command enables or disables the persistence display mode.
Command Syntax
PERSIST <mode>
<mode>:= {ON, OFF}
Query Syntax
PERSIST?
Response Format
PERSIST <mode>
Example (GPIB)
The following instruction turns the persistence display ON:
CMD$="PERS ON": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PERSIST_COLOR, PERSIST_LAST, PERSIST_SAT, PERSIST_SETUP
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PERSIST_SAT, PESA
Description
The PERSIST_SAT command sets the saturation level of the persistence color spectrum. The level is
specified in terms of percentage (PCT) of the total persistence data map population. A level of 100 PCT
corresponds to the color spectrum being spread across the entire depth of the persistence data map. At
lower values, the spectrum saturates (brightest value) at the specified percentage value. The unit PCT is
optional.
The response to the PERSIST_SAT? query indicates the saturation level of the persistence maps.
Command Syntax
PERSIST_SAT <trace>,<value>[...,<trace>,<value>]
<trace>:= C1 to Cx, F1 to Fx, TA to TD
<value>:= 0 to 100
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
Query Syntax
PERSIST_SAT?
Response Format
PERSIST_SAT <trace>,<value>
Example (GPIB)
The following instruction sets the saturation level of the persistence data map for channel 3 to 60%. This
means 60% of the data points are displayed with the color spectrum, and the remaining 40% saturated in
the brightest color:
CMD$="PESA C3,60": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PERSIST, PERSIST_COLOR, PERSIST_PERS, PERSIST_SETUP
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PERSIST_SETUP, PESU
Description
The PERSIST_SETUP command selects the persistence duration of the display, in seconds, in persistence
mode. The persistence can also be set on either all traces or only the top two shown on the screen.
The PERSIST_SETUP? query indicates the current status of the persistence.
Command Syntax
PERSIST_SETUP <time>,<mode>
<time>:= {0.5, 1, 2, 5, 10, 20, infinite}
<mode>:= {PERTRACE, ALL}
Note: This command does not support the argument Top2 of legacy instruments.
Query Syntax
PERSIST_SETUP?
Response Format
PERSIST_SETUP <time>,<mode>
Example (GPIB)
The following instruction sets the variable persistence to 10 seconds on all traces:
CMD$="PESU 20,ALL": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PERSIST, PERSIST_COLOR, PERSIST_PERS, PERSIST_SAT
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Part 6: IEEE 488.2 Command Reference
TRACE, TRA
Description
The TRACE command enables or disables the display of a trace. An environment error is set if an attempt
is made to display more than four waveforms. Refer to the EXR table in the EXR? topic for more
information.
The TRACE? query indicates whether or not the specified trace is displayed.
Command Syntax
<trace>:TRACE <mode>
<trace>:= C1 to Cx, F1 to Fx, TA to TD
<mode>:= {ON, OFF}
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
Query Syntax
<trace>:TRACE?
Response Format
<trace>:TRACE <mode>
Example (GPIB)
The following instruction displays Trace F1:
CMD$="F1:TRA ON": CALL IBWRT(SCOPE%,CMD$)
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VERT_MAGNIFY, VMAG
Description
The VERT_MAGNIFY command vertically expands the specified trace. The command is executed even if
the trace is not displayed. The maximum magnification allowed depends on the number of significant bits
associated with the data of the trace.
The VERT_MAGNIFY? query returns the magnification factor of the specified trace.
Command Syntax
<trace>:VERT_MAGNIFY <factor>
<trace>:= F1 to Fx, TA to TD
<factor>:= 100E-3 to 181
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
Query Syntax
<trace>:VERT_MAGNIFY?
Response Format
<trace>:VERT_MAGNIFY <factor>
Example (GPIB)
The following instruction enlarges the vertical amplitude of Trace A by a factor of 3.45 with respect to its
original amplitude:
CMD$="TA:VMAG 3.45": CALL IBWRT(SCOPE%,CMD$)
Related Commands
VERT_POSITION
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Part 6: IEEE 488.2 Command Reference
VERT_POSITION, VPOS
Description
The VERT_POSITION command adjusts the vertical position of the specified trace on the screen. It does
not affect the original offset value obtained at acquisition time.
The VERT_POSITION? query returns the current vertical position of the specified trace.
Note: The VPOS command and query can only be applied to math function and memory traces. It
does not apply to channel inputs.
Command Syntax
<trace>:VERT_POSITION <display_offset>
<trace>:= F1 to Fx, M1 to Mx, TA to TD
<display_offset>:= -5900 to +5900 DIV
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
The unit DIV is optional. The limits depend on the current magnification factor, the number of grids on the
display, and the initial position of the trace.
Query Syntax
<trace>:VERT_POSITION?
Response Format
<trace>:VERT_POSITION <display_offset>
Example (GPIB)
The following instruction shifts trace F1 upwards by +3 divisions relative to the position at the time of
acquisition:
CMD$="F1:VPOS 3DIV": CALL IBWRT(SCOPE%,CMD$)
Related Commands
VERT_MAGNIFY
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FUNCTION Commands and Queries
CLEAR_MEMORY, CLM
Description
The CLEAR_MEMORY command clears the specified memory. Data previously stored in this memory are
erased and memory space is returned to the free memory pool.
Command Syntax
CLEAR_MEMORY <memory>
<memory>:= M1 to Mx
Example (GPIB)
The following instruction clears the memory M2.
CMD$="CLM M2": CALL IBWRT(SCOPE%,CMD$)
Related Commands
STORE
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Part 6: IEEE 488.2 Command Reference
CLEAR_SWEEPS, CLSW
Description
The CLEAR_SWEEPS command restarts the cumulative processing functions: summed or continuous
average, extrema, FFT power average, histogram, pulse parameter statistics, Pass/Fail counters, and
persistence.
Command Syntax
CLEAR_SWEEPS
Example (GPIB)
The following example restarts the cumulative processing:
CMD$="CLSW": CALL IBWRT(SCOPE%,CMD$)
Related Commands
INR
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FUNCTION - DEFINE, DEF
Description
The DEFINE command specifies the mathematical expression to be evaluated by a function. This
command is used to control all math tools in the standard oscilloscope along with those in the optional
math software packages.
Only functions available on your instrument may be specified as parameters.
Refer to your oscilloscope Operator's Manual for details regarding the standard operators. See software
option manuals for other math operators.
Command Syntax
<function>:DEFINE <parameter>,<value>[,<parameter>,<value>,...]
<function>:= F1 to Fx
Parameters are specified in pairs. The first in the pair names the parameter to be modified, <param_
name>, while the second one gives the new value to be assigned. As many pairs may be added as are
needed. Pairs can be given in any order and restricted to the variables to be changed.
See the Equation Notation and following tables for formatting of the <equation> value and additional
parameters related to each operation. Space characters inside equations are optional.
Tip: The best way to learn the required syntax is to set up the function as desired on the
oscilloscope and run the Fx: DEF? query. The response will be formatted exactly as required,
especially if you have set the oscilloscope to suppress command headers using COMM_HEADER.
Query Syntax
<function>:DEFINE?
Response Format
<function>:DEFINE EQN,'<equation>'[,<parameter>,<value>,...]
Function Parameters
At least one of the following parameter pairs is required for the command. Generally, this is the EQN
parameter, but other parameters shown can be sent as incremental changes to current EQN.
Parameters Values Description
EQN '<equation>' Mathematical operation to perform. Enclose the operation in quotes. Follow
with additional parameter pairs as needed. See table below.
BITS <num bits> Number of bits to interpolate in ERES equation.
CENTER <time or div> Horizontal center position for Histogram function.
LENGTH <length> Number of points to use from first waveform in Correlate function.
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Parameters Values Description
MAXEVENTS <#events> Number of events computed in Histogram function. See product datasheet for
maximum value.
MAXBINS <#bins> Number of bins used to compute Histogram.
START <start> Starting point in second waveform for Correlate function.
SWEEPS <#sweeps> Number of sweeps used to compute function. See the product datasheet for
maximum value.
UNITS <unit> Physical unit in which to express function result. See table of unit mnemonics.
VERT <vert_scale> Vertical scaling type.
WEIGHT <weight> Continuous Average function weighting factor.
WIDTH <width> Width of histogram display.
WINDOW <window_type> FFT window function. See FFT operator for list of window types.
Equation Notation
The equation value is a string comprised of the math operator followed immediately by the source(s) in
parentheses. Enclose the entire equation string in quotes. Follow the equation pair with any additional
parameter pairs relevant to the operation. For example:
F1:DEFINE EQN,'AVG(C1)',AVERAGETYPE,SUMMED
Include text in caps and special characters (e.g., parentheses) as shown in the tables below. Substitute
variable text shown here in angle brackets with acceptable values. Use one of the values listed in curly
brackets.
All MAUI Oscilloscopes
These operators are standard on all MAUI oscilloscopes running XStream v. 8.0.0 or higher.
Operators Additional Parameters Description
ABS( <source>) Absolute Value
AVG (<source>) AVERAGETYPE,
{SUMMED,CONTINUOUS}
WEIGHT,<value>
Average of single waveform.
Specify WEIGHT for Continuous
Averaging.
DERI(<source>) VERSCALE,<verscale>
VEROFFSET,<veroffset>
ENABLEAUTOSCALE,{ON, OFF}
Derivative of waveform using sub-
traction of adjacent samples.
<source1>–<source2> Difference between two waveforms.
FFT(<source>) TYPE,{REAL, IMAGINARY, MAGNITUDE,
PHASE, POWERSPECTRUM,
POWERDENSITY }
WINDOW,{BLACKMANHARRIS,
FLATTOP, HAMMING, RECTANGULAR,
VONHANN}
ALGORITHM,{LEASTPRIME, POWER2}
FILLTYPE,{TRUNCATE, ZEROFILL}
SUPPRESSDC,{ON, OFF}
Fast Fourier Transform of waveform.
For FFT average of power spectrum
and FFT power average of power
density, use the summed average of
the corresponding FFT type, e.g.:
EQN,"AVG(FFT(C1))",
TYPE,POWERSPECTRUM,
AVERAGETYPE,SUMMED
ERES(<source>) BITS,{0.5, 1.0, 1.5, 2.0, 2.5, 3.0 } Smoothing function defined by extra
bits of resolution.
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Operators Additional Parameters Description
FLOOR(<source>) SWEEPS,<value> Lowest vertical value at each X value
in N sweeps.
INTG(<source>) MULTIPLIER,< 0.0 to 1e15>
ADDER,<0.0 to 1e15>
VERSCALE,<value>
VEROFFSET,<value>
Integral
INVERT(-<source>) Inversion (negation) of waveform.
PRODUCT <source1>*<source2> Product of two waveforms.
RATIO <source1>/<source2> Ratio of two waveforms.
RECIPROCAL 1/<source> Reciprocal of a waveform.
RESC(<source>) MULTIPLIER,< 0.0 to 1e15>
ADDER,<0.0 to 1e15>
UNIT,{value}
Rescale waveform as Out = A*Wave
(In) + B. See list of Units below for val-
ues.
ROOF(<source>) SWEEPS,<value> Highest Y value at each X in a set of
waveforms.
SQR(<source>) Square of waveform values.
SQRT(<source>) Square root of waveform values.
SUM<source1>+<source2> Sum of two waveforms.
TREND(<source>) AUTOFINDSCALE,{ON, OFF}
VERSCALE,<value>
CENTER,<time or div>
Trend of the values of a parameter.
ZOOMONLY(<source>) VERSCALE,<value>
HORSCALE,<value>
Zoom of waveform
HDO6000 and Higher Bandwidth Oscilloscopes
These operators are standard on HDO6000 and higher, MDA, WaveRunner 8000, WaveRunner/HRO 6 Zi,
DDA/SDA/WavePro 7 Zi, DDA/SDA/WaveMaster 8 Zi, and LabMaster series oscilloscopes running
XStream v. 8.0.0 or higher.
Operators Additional Parameters Description
CORR(<source1>,<source2>) LENGTH,<length>
START,<start point>
Correlation of two waveforms with
specified correlation length and start
point in second waveform.
DESKEW(<source>) WAVEDESKEW,<value> Shift waveform in time by a specified
amount.
EXP(<source>) Exponential (power of e).
EXP10(<source>) Exponential (power of 10).
EXTR(<source>) SWEEPS,<value> Extrema (Roof and Floor) of wave-
form. Same as Envelope.
HIST(<source>) BINS,<value>
MAXEVENTS,<value>
HORSCALE,<value>
CENTER,<value>
VERSCALETYPE,{LINEAR,
LINCONSTMAX}
Histogram of parameter values whe
using Px source; Histogram of wave-
form data when using Cx source.
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Operators Additional Parameters Description
AUTOFINDSCALE,{ON, OFF}
INTRP(<source>) INTERPOLATETYPE,{LINEAR,
QUADRATIC, SINXX}
EXPAND,{ON, OFF}
Interpolate extra points in waveform.
LN(<source>) Natural logarithm of waveform.
LOG10(<source>) Base 10 logarithm of waveform.
PERHIST(<source>) VERCUTCENTER,<value>
VERCUTWIDTH,<value>
HORCUTCENTER,<value>
HORCUTWIDTH,<value>
CUTDIRECTION,<value>
CUTTYPE,<value>
CUTWIDTH,<value>
Phistogram: histogram of a slice
through a persistence map.
PMEAN(<source>) Waveform derived from the mean of a
persistence map.
PRANGE(<source>) PCTPOPULATION,<value> Waveform derived from the range of
a persistence map.
PSIGMA(<source>) SIGMA,<value> Waveform derived from the st dev of
a persistence map.
PHSHIFT(<source>) PHASE,<value> Change the phase of a set of com-
plex data.
SEG(<source>) SELECTEDSEGMENT,<value> Select one segment from a sequence
acquisition.
SINX(<source>) Ten times interpolation using sin(x)/x.
SLICE(<source1>,<source2>) FREQUENCY,<value>
PRIORPERIODS,<value>
POSTPERIODS,<value>
Slices source2 waveform to make
many waveforms, using wf 1.
SPACK(<source>) Magnitude of complex result.
SPARSE(<source>) SPARSINGFACTOR,<value>
SPARSINGPHASE,<value>
Produces as waveform with fewer
points than the input.
TRACK(<source>) AUTOFINDSCALE,{ON, OFF}
VERSCALE,<value>
CENTER,<time or div>
Track of the values of a parameter.
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Operators Available with XDEV Option
These operators are standard on DDA/SDA/WavePro 7 Zi, and DDA/SDA/WaveMaster 8 Zi, and
LabMaster series oscilloscopes running XStream v. 8.0.0 or higher. They are available elsewhere with the
installation of the XDEV option.
Operator Additional Parameters Description
EXCELMATH(<source1>,<source2>) SOURCE1CELL,<cell>
SOURCE2CELL,<cell>
OUTPUTCELL,<cell>
SOURCE1HEADERCELL,<cell>
SOURCE2HEADERCELL,<cell>
OUTPUTHEADERCELL,<cell>
WITHHEADER, {ON, OFF}
OUTPUTENABLE, {ON, OFF}
SOURCE1ENABLE, {ON, OFF}
SOURCE2ENABLE, {ON, OFF}
NEWSHEET, {ON, OFF}
ADVANCED, {ON, OFF}
SCALING, {AUTOMATIC, MANUAL,
FROMSHEET}
{AUTOMATIC,MANUAL,FROMSHEET}
SPREADSHEETFILENAME,<file.xls>
Produces a waveform using a
custom Excel function, and outputs
results to Excel spreadsheet.
Use full path to spreadsheet file
name.
FASTWAVEPORT(<source>) MAXSIZE,<value SAMPLE>,
TIMEOUT,<value S>,
PORTNAME,FASTWAVEPORT1
Produces a waveform using an
external, user-defined function.
MATLAB(<source1>,<source2>) MATLABCODE,<formula>
MATLABPLOT, {ON, OFF}
MATLABZEROOFFSET,<value>
MATLABSCALEPERDIV,<value>
Produces a waveform using custom
MATLAB function.
MCAD(<source1>,<source2>) SOURCE1VAR,<value>
SOURCE2VAR,<value>
OUTPUTVAR,<value>
SOURCE1HEADERVAR,<value>
SOURCE2HEADERVAR,<value>
OUTPUTHEADERVAR,<value>
WITHHEADER,{ON, OFF}
Produces a waveform using custom
MathCad function.
SCRIPT(<source1>,<source2) LANGUAGE,VBSCRIPT.
CODE,<VBScript code>,
TIMEOUT,<value>
Produces waveform from applied
VBS function.
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Operators Available with DFP Option
These operators are available with the installation of the Digital Filter Package option.
Operators Additional Parameters Description
FILTER(<source>) FIRORIIR,{FIR, IIR}
FILTERKIND,{LOWPASS, HIPASS,
PASSBAND}
FILTERTYPE,{BESSEL, BUTTERWORTH,
CHEBYSHEV, INVCHEBYSHEV}
KAISERBETA,<value> PCT
GAUSSIANBT,<value> PCT
COSINEBETA,<value> PCT
TRANSITIONWIDTH,<value> HZ
F3DBWIDTH,<value> HZ
STOPBANDATTENUATION,<value> DB
PASSBANDRIPPLE,<value> DB,
PASSBANDATTENUATION,<value> DB
LOWFREQSTOP,<value> HZ
LOWFREQPASS,<value> HZ
HIGHFREQSTOP,<value> HZ
HIGHFREQPASS,<value> HZ
F3DBFREQ,<value> HZ
CORNERFREQ,<value> HZ
CENTERFREQ,<value> HZ
ROLLOFF,<value>
NUMBEROFTAPS,<value>
NUMBEROFSTAGES,<value>
ADVANCED,{ON, OFF}
AUTOLENGTH,{ON, OFF}
Digital filter, available with DFP
option.
FIR(<source>) FTYPE,{LOWPASS, HIPASS,
BANDPASS, BANDSTOP, RAISEDCOS,
RSDROOTCOS, GAUSSIAN, CUSTOM}
FREQ,<lower or only corner freq. in HZ>
UFREQ,<upper corner freq.lfreq in HZ>
FWIDTH,<transition region in HZ>
FBETA,<0 to 100% >
MCOEFF,<M1 to Mx>
Finite Impulse Response filter, avail-
able with DFP option.
FWIDTH must be >0.3% of sample
rate. <lfreq> - <fwidth> must be 0.1%
of sample rate.
For raised cos and raised root cos,
FBETA is % of <lfreq> + and - over
which transition region extends. For
Guassian, % of <lfreq> at which
response is 3dB down from DC.
Examples
The following instruction defines F1 to compute the summed average of C1 over 200 sweeps:
F1:DEF EQN,'AVG(C1)',AVRAGETYPE,SUMMED,SWEEPS,200
The following instruction defines F1 to compute the product of C1 and C2:
F1:DEF EQN,'C1*C2'
The following instruction defines F1 to compute the Power Spectrum of the FFT of C1. The window
function is Rectangular.
F1:DEF EQN,'PS(FFT(C1))',WINDOW,RECT
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The following instruction defines F2 to compute the Power Average of the Power Spectrum of C1 over 244
sweeps.
F2:DEF EQN,'AVG(FFT(C1)'
TYPE,POWERSPECTRUM,WINDOW,RECT,ALGORITHM,POWER2,FILLTYPE,TRUNCATE,
SUPPRESSDC,ON,AVERAGETYPE,SUMMED,SWEEPS,244
The following instructions define F3 to construct the histogram of the P2 rise time measurements. The
histogram has a linear vertical scaling, accumulates up to 1000 parameter values, and rescales
automatically. The rise time parameter values are binned into 100 bins.
F3:DEF EQN,'HIST(P2)',VALUES,1000,BINS,100,HORSCALE,1 S,
CENTER,0E-12 S,VERSCALETYPE,LINEAR,AUTOFINDSCALE,ON
The following instruction defines F1 to correlate C1 and C2 for 5 divisions starting at division
F1:DEF EQN,"CORR(C1,C2)",CORRLENGTH,5 DIV,CORRSTART,0E-3 DIV
The following instruction defines F1 to take the derivative of C1:
F1:DEF EQN,"DERI(C1)",VERSCALE,1E+6 V/S,VEROFFSET,48E+3 V/S,ENABLEAUTOSCALE,ON
The following instruction defines F1 to Enhance Resolution of the C1 trace by interpolating .5 bits between
each sample point:
F1:DEF EQN,"ERES(C1)",BITS,0.5
Related Commands
FIND_CTR_RANGE, FUNCTION_RESET, INR?, PARAMETER_CUSTOM, PARAMETER_VALUE?, PASS_FAIL_
CONDITION
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FIND_CTR_RANGE, FCR
Description
The FIND_CTR_RANGE command automatically sets the center and width of a histogram to best display
the accumulated events.
FIND_CTR_RANGE is only available with an option installed that includes Histograms.
Command Syntax
<function>:FIND_CTR_RANGE
<function>:= TA to TD, F1 to Fx
Example (GPIB)
Assuming that Trace A (TA) has been defined as a histogram of one of the custom parameters, the
following example determines the best center and width, and then rescales the histogram:
CMD$="TA:FCR": CALL IBWRT(SCOPE%,CMD$)
Related Commands
DEFINE, PARAMETER_CUSTOM
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FUNCTION_RESET, FRST
Description
The FUNCTION_RESET command resets a waveform processing function. The number of sweeps is reset
to zero and the process restarted.
Command Syntax
<function>:FUNCTION_RESET
<function>:= F1 to Fx, TA to TD
Example (GPIB)
Assuming that Trace F1 has been defined as the summed average of Channel 1, the following will restart
the averaging process:
CMD$="F1:FRST": CALL IBWRT(SCOPE%,CMD$)
Related Commands
INR
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Part 6: IEEE 488.2 Command Reference
HARDCOPY Commands and Queries
HARDCOPY_SETUP, HCSU
Description
The HARDCOPY_SETUP command configures the instrument's hard copy (print) driver. It enables you to
specify the device type and transmission mode of the hard copy unit connected to the instrument. This
can be the instrument clipboard or hard drive, as well as a printer.
One or more individual settings can be changed by specifying the appropriate keywords, together with the
new values. If you send contradictory values within a command, the result is governed by the last one
sent.
The HARDCOPY_SETUP query returns the oscilloscope's current hardcopy settings.
Command Syntax
HARDCOPY_SETUP DEV,<device>,FORMAT,<format>,BCKG,<bckg>,
DEST,<destination>,DIR,"<directory>",AREA,<hardcopyarea>
[,FILE,"<filename>",PRINTER,"<printername>",PORT,<portname>]
<device>:= {BMP, JPEG, PNG, TIFF}
<format>:= {PORTRAIT, LANDSCAPE}
<bckg>:= {BLACK, WHITE}
<destination>:= {PRINTER, CLIPBOARD, EMAIL, FILE, REMOTE}
<area>:= {GRIDAREAONLY, DSOWINDOW, FULLSCREEN}
<directory>:= legal DOS path, for FILE mode only
<filename>:= filename string, no extension, for FILE mode only
<printername>:= valid printer name, for PRINTER mode only
<portname>:= {GPIB, NET}
Hardcopy command parameters are grouped in pairs. The first in the pair names the variable to be
modified, while the second gives the new value to be assigned. Pairs can be given in any order and can be
restricted to those variables to be changed. Omitted variables remain unaffected.
The <device> types PSD and BMPCOMP are not supported on MAUI oscilloscopes.
Strings representing the names of directories, files, or printers that may contain spaces and other non-
alphanumeric characters must be enclosed in quotes.
An autoincremented number is appended to the <filename> string with each successive capture.
The <portname> is included for backward compatibility and sets DEST, REMOTE regardless of what else is
specified in the HCSU command.
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Query Syntax
HCSU?
Response Format
If preceded, for example, by HCSU DEST,FILE with CHDR OFF:
DEV,PNG,FORMAT,PORTRAIT,BCKG,BLACK,DEST,REMOTE,
DIR,"C:\LECROY\XSTREAM\HARDCOPY",
FILE,"IRHCP1.PNG",AREA,GRIDAREAONLY,PRINTER,"GENEVSVRHP4050RD"
Example (GPIB)
The following example selects output to the printer named "Local Printer":
CMD$="HCSU DEST,PRINTER,PRINTER,"Local Printer"" :CALL IBWRT(SCOPE%,CMD$)
Related Commands
SCREEN_DUMP
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SCREEN_DUMP, SCDP
Description
The SCREEN_DUMP command causes the instrument to send the screen contents to the current
hardcopy device. The time-and-date stamp corresponds to the time of the command.
Command Syntax
SCREEN_DUMP
Query Syntax
SCREEN_DUMP?
Response Format
SCREEN_DUMP <status>
Example (GPIB)
The following instruction initiates a screen dump:
CMD$="SCDP": CALL IBWRT(SCOPE%,CMD$)
Related Commands
INR, HARDCOPY_SETUP
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MISCELLANEOUS Commands and Queries
AUTO_CALIBRATE, ACAL
Description
The AUTO_CALIBRATE command is used to enable or disable the automatic calibration of your XStream
oscilloscope. At power-up, auto-calibration is turned ON, i.e. all input channels are periodically calibrated
for the current input amplifier and timebase settings, whether the instrument has been adjusted or not.
Whenever you adjust a gain or offset, however, the instrument performs a calibration. This action occurs
whatever the current state of ACAL, and it does not change the state of ACAL.
Automatic calibration can be disabled by means of the command ACAL OFF. But whenever convenient,
you can issue a *CAL? query to fully calibrate the oscilloscope. When the oscilloscope is returned to local
control, periodic calibrations are resumed if the last ACAL value was ON. That is, the command *CAL? has
no effect on the ACAL status.
The response to the AUTO_CALIBRATE? query indicates whether auto-calibration is enabled or disabled.
Command Syntax
AUTO_CALIBRATE <state>
<state> : = {ON, OFF}
Query Syntax
AUTO_CALIBRATE?
Response Format
AUTO_CALIBRATE <state>
Example (GPIB)
The following instruction disables auto-calibration:
CMD$="ACAL OFF": CALL IBWRT(SCOPE%,CMD$)
Related Commands
*CAL?
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Part 6: IEEE 488.2 Command Reference
BUZZER, BUZZ
Description
The buzzer command controls the built-in buzzer. By means of the BEEP argument, the buzzer can be
activated for short beeps. The value ON has the same effect as BEEP, unlike the behavior with earlier
instruments. ON and OFF are accepted only for compatibility. OFF has no effect.
Command Syntax
BUZZer <state>
<state>:= {BEEP, ON, OFF}
Example (GPIB)
Sending the following will cause the instrument to sound two short tones:
CMD$="BUZZ BEEP;BUZZ BEEP":
CALL IBWRT(SCOPE%<CMD$)
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*CAL?
Description
The *CAL? query causes the oscilloscope to perform an internal self-calibration and generates a response
that indicates whether or not the calibration completed without error. This internal calibration sequence is
the same as that which occurs at power-up. At the end of the calibration, after the response, the
oscilloscope returns to the state it was in just prior to the calibration cycle. This includes the AUTO_
CALIBRATE status, which is not affected by the use of *CAL?; the *CAL? query may be used whether
AUTO_CALIBRATE has been set on or off.
Query Syntax
*CAL?
Response Format
*CAL? <diagnostics>
<diagnostics>:= diagnostic code 0 through 64
Where:
0 = Calibration successful
1 = C1 Cal error
2 = C2 Cal error
4 = C3 Cal error
8 = C4 Cal error
16 = TDC failure
32 = Trigger failure
64 = Other
Example (GPIB)
The following instruction forces a self-calibration:
CMD$="*CAL?": CALL IBWRT(SCOPE%,CMD$): CALL IBRD(SCOPE%,RD$): PRINT RD$
Response message if no failure:
*CAL 0
Related Commands
AUTO_CALIBRATE
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CAL_OUTPUT, COUT
Description
The CAL_OUTPUT command is used to set the type of signal put out through the instrument front panel's
CAL BNC connector.
Command Syntax
CAL_OUTPUT <mode>[,<level>[,<rate>]]
CAL_OUTPUT PULSE[,<width>]
<mode> : = {OFF, CALSQ, PF, TRIG, LEVEL, ENABLED}
<level> : = 5 mV to 1.00 V into 1 M
<rate> : = 5 Hz to 5 MHz.
CALSQ provides a square signal; PF sets the pulse for Pass/Fail mode; TRIG sets the pulse for trigger
output; LEVEL provides a DC signal at the requested level; PULSE provides a single pulse
Query Syntax
CAL_OUTPUT?
Response Format
CAL_OUTPUT <mode>,<level>[,<rate>]
Example (GPIB)
The following instruction sets the calibration signal to give a 0 to 0.2 volt 10 kHz square wave:
CMD$="COUT CALSQ,0.2 V,10 kHz":
CALL IBWRT(SCOPE%,CMD$)
Related Commands
PASS_FAIL_DO
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DATE
Description
The command sets the date and time of the real-time clock in the instrument. The query reads back the
instrument timestamp.
Command Syntax
Using this command to set the clock from the Internet will work on MAUI oscilloscopes that have an
internet connection, but you must Validate Changes on the oscilloscope itself for them to take effect. To
set the date and the time from the internet:
DATE SNTP
Query Syntax
DATE?
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*IDN?
Description
The *IDN? query causes the instrument to identify itself. The response comprises manufacturer,
oscilloscope model, serial number, and firmware revision level.
Query Syntax
*IDN?
Response Format
*IDN LECROY,<model>,<serial_number>,<firmware_level>
<model>:= A six- or seven-character model identifier
<serial_number>:= A nine- or 10-digit decimal code
<firmware_level>:= version number
The version number is in dotted decimal format: two digit major release number, one digit minor release
number, one digit update number (xx.y.z).
Example (GPIB)
This issues an identification request to the oscilloscope:
CMD$="*IDN?": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD(SCOPE%,RSP$): PRINT RSP$
Response message:
*IDN LECROY,WAVEMASTER,WM01000,3.3.0
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*OPT?
Description
The *OPT? query identifies oscilloscope options: installed software or hardware that is additional to the
standard instrument configuration. The response consists of a series of response fields listing all the
installed options.
Query Syntax
*OPT?
Response Format
*OPT <option_1>,<option_2>,..,<option_N>
<option_n>:= A three- or four-character ASCII string
Note: If no option is present, the character 0 is returned.
Example (GPIB)
The following instruction queries the installed options:
CMD$="*OPT?": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD(SCOPE%,RSP$): PRINT RSP$
If, for example, the waveform processing options DFP2, SDM, JTA2, and GPIB are installed, the response is
returned as:
* DFP2,SDM,JTA2,GPIB
Response message if no options are installed:
*OPT 0
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*TST?
Description
The *TST? query performs an internal self-test, the response indicating whether the self-test has detected
any errors. The self-test includes testing the hardware of all channels, the timebase and the trigger
circuits.
Hardware failures are identified by a unique binary code in the returned <status> number. A status of 0
indicates that no failures occurred.
Query Syntax
*TST?
Response Format
*TST <status>
Example (GPIB)
The following causes a self-test to be performed:
CMD$="*TST?": CALL IBWRT(DDA%,CMD$):
CALL IBRD(DDA%,RD$): PRINT RD$
Response message (if no failure):
*TST 0
Related Commands
*CAL
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PROBE Commands
PROBE_INFOTEXT?, PRIT?
Description
The PROBE_INFOTEXT query returns informative text about a probe connected to the oscilloscope.
Query Syntax
<channel>:PROBE_INFOTEXT?
<channel>:= C1 to Cx, EX, EX5
Response Format
<channel>:PRIT "<info>"
Related Commands
PROBE_CAL?, PROBE_DEGAUSS?
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PROBE_NAME?, PRNA?
Description
The PROBE_NAME? query returns the name of a probe connected to the instrument. Passive probes are
identified by their attenuation factor.
Query Syntax
<channel>:PROBE_NAME?
<channel>:= C1 to Cx, EX, EX5
Response Format
<channel>:PROBE_NAME <name>
Related Commands
PROBE_CAL?, PROBE_DEGAUSS?
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PRx:AUTOZERO, PRx:AZ
Description
The PRx:AUTOZERO command initiates an auto zero cycle in the ADP30x probe to remove any offset
drift. The probe input can remain connected to the test circuit during the auto zero cycle.
Command Syntax
<channel>:AUTOZERO
<channel>:= {PR1, PR2, PR3, PR4}
Example (GPIB)
The following command initiates an AutoZero of an ADP30x probe attached to channel 1:
CMD$= "PR1:AZ" : CALL IBWRT(SCOPE%,CMD$)
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PRx:BANDWIDTH_LIMIT, PRx:BWL
Description
The PRx:BANDWIDTH_LIMIT command sets the upper (HF) –3 dB bandwidth limit of the ADP305 probe.
The arguments are in Hz.
The PRx:BANDWIDTH_LIMIT query returns the upper bandwidth limit setting for the differential probe
connected to the specified channel.
The PRx:BANDWIDTH_LIMIT command/query is not available with model ADP300.
Command Syntax
<channel>:BWL <upper bandwidth>
<channel>:= {PR1, PR2, PR3, PR4}
<upper bandwidth>:= {OFF, 20M}
Query Syntax
<channel>:BWL?
Response Format
<channel>:BWL <upper bandwidth>
Example (GPIB)
The following instruction sets the upper bandwidth of an ADP305 connected to channel 1 to 20 MHz.
CMD$= "PR1:BWL 20M" :CALL IBWRT(SCOPE%,CMD$)
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PRx:COUPLING, PRx:CPL
Description
The PRx:COUPLING command selects the coupling mode of the ADP30x probe.
The PRx:COUPLING? query returns the coupling mode of the selected channel.
Command Syntax
<channel>:COUPLING <coupling>
<channel>:= {PR1, PR2, PR3, PR4}
<coupling>:= {DC, GND}
Query Syntax
<channel>:CPL?
Response Format
<channel>:CPL <coupling>
Example
The following instruction sets the coupling to DC in a ADP30x probe connected to channel 2.
CMD$= "PR2:CPL DC" : CALL IBWRT(SCOPE%,CMD$)
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PRx:OFFSET, PRx:OFST
Description
When an ADP30x probe is connected to a channel, the OFFSET command sets the probe offset value. The
maximum range and resolution is determined by the V/DIV setting. If an out-of-range value is entered, the
differential probe will set the offset to the closest valid value, and the VAB bit (bit 2) in the STB register will
be set.
The OFFSET? query returns the offset voltage of the differential probe connected to the specified
channel.
Command Syntax
<channel>:OFFSET <offset>[V]
<channel>:= {PR1, PR2, PR3, PR4}
V/Div Range Offset Ranges
ADP305 200-499 mV/div (LC series) -40V to 40V
200-499 mV/div (LT series) -100V to 100V
500 mV/div to 9.9 V/div -100V to 100V
10V/div to 99 V/div -1000V to 1000V
100 V/div to 350 V/div -1400V-(4*V/div setting) to 1400V-(4*V/div setting)
ADP300 1 to 9.9 V/div -100V to 100V
10 to 99 V/div -1000V to 1000V
100 V/div to 350 V/div -1400V-(4*V/div setting) to 1400V-(4*V/div setting)
Query Syntax
<channel>:OFST?
Response Format
<channel>:OFST <offset>
Example (GPIB)
The following command sets the offset at the probe tip of the ADP30x differential probe connected to
channel 1 to 5 volts:
CMD$= "PR1:OFST 5" : CALL IBWRT(SCOPE%,CMD$)
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PRx:VOLT_DIV, PRx:VDIV
Description
The PRx:VOLT_DIV command sets the vertical sensitivity at the ADP30x input. The effective gain of the
differential probe is factored into the vertical sensitivity.
The valid range of arguments is fixed by the probe type. If an out-of-range value is entered, the
oscilloscope will set the vertical sensitivity to the closest value and set the VAB bit (bit 2) in the STB
register.
The PRx:VOLT_DIV? query returns the vertical sensitivity at the probe input of the specified channel.
Command Syntax
<channel>:VOLT_DIV <sensitivity> [V]
<channel>:= {PR1, PR2, PR3, PR4}
<sensitivity>:= 200 mV to 350 V for ADP350; 1 V to 350 V for ADP300.
The suffix V is optional.
Query Syntax
<channel>:VOLT_DIV?
Response Format
<channel>:VDIV <sensitivity>
Example (GPIB)
The following command sets the vertical sensitivity at the probe tip of an ADP30x probe connected to
channel 3 to 2 Volts/div:
CMD$= "PR3:VDIV 2" :CALL IBWRT(SCOPE%,CMD$)
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Part 6: IEEE 488.2 Command Reference
SAVE/RECALL SETUP Commands and Queries
PANEL_SETUP?, PNSU?
Description
The PANEL_SETUP query returns all oscilloscope setups in ASCII format, which can be saved to an .LSS
file to be recalled to the oscilloscope using RECALL_SETUP.
Only setup data previously read by the PNSU? query or saved using the STORE_PANEL command can be
recalled into the oscilloscope. A panel setup error is generated if the setup data block contains invalid
data. See the Execution Error Status Register (EXR) table in EXR? for more information.
Note: The communication parameters (modified by commands CFMT, CHDR, CHLP, CORD and
WFSU) and the enable registers associated with the status reporting system (SRE, PRE, ESE, INE)
are not saved by this command.
Query Syntax
PANEL_SETUP?
Response Format
PANEL_SETUP <setup>
Related Commands
*RCL, *SAV
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*RCL (Recall Setup)
Description
The *RCL command sets the instrument state by recalling one of the non-volatile setup panels (Setup 0 to
Setup x).
The *RCL command produces an effect the opposite of the *SAV command.
If the specified setup is not acceptable, the Execution Error Status Register (EXR) is set and the EXE bit of
the standard Event Status Register (ESR) is set.
Command Syntax
*RCL <panel_setup>
<panel_setup>:= 0 to x
0 is the factory default panel setup.
1 to xare the corresponding setup panels available on your oscilloscope. The maximum value of xwill be
the highest number setup (e.g., 6 indicating Setup 6).
Example (GPIB)
The following instruction recalls the instrument setup previously stored in Setup 3:
CMD$="*RCL 3": CALL IBWRT(SCOPE%,CMD$)
Related Commands
RECALL_PANEL, PANEL_SETUP, *SAV, ESR, EXR
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Part 6: IEEE 488.2 Command Reference
RECALL_PANEL, RCPN
Description
The RECALL_PANEL command recalls panel setups from a file saved (using PNSU? or
STORE_PANEL) on the instrument data drive (D:) or a connected mass storage device. The device and the
file name are given as two-value parameter pairs.
Command Syntax
RECALL_PANEL DISK,<device>,FILE,'<file name>'
<device>:= {HDD, USB, MICRO}
<file name>:= full path to file with the extension .LSS
The file name string may be up to eight characters. Use the full path to the directory, including the drive
letter, enclosed in single quotes. Be sure there are no spaces before the directory string.
Note: The hard drive selection (HDD) always points to drive D, which is the data drive on MAUI
oscilloscopes. An external USB drive is usually named drive E; check your oscilloscope file system.
The device type MICRO applies only to instruments that utilize Micro-SD card data storage, such
as WaveSurfer 3000.
Example (GPIB)
The following instruction recalls the panel setup from file CHIRP_MEAS.LSS on the instrument D: drive:
CMD$="RCPN DISK,HDD,FILE,'D:\Applications\USB2\Setups\CHIRP_MEAS.LSS'": CALL IBWRT
(SCOPE%,CMD$)
The following instruction recalls the panel setup from file CHIRP_MEAS.LSS on a USB drive connected to
the instrument, where the file is stored in the \USB2\Setups subfolders:
CMD$="RCPN DISK,USB,FILE,'E:\USB2\Setups\CHIRP_MEAS.LSS'": CALL IBWRT(SCOPE%,CMD$)
The following instruction recalls the panel setup from file P012.LSS on a USB drive:
CMD$="RCPN DISK,USB,FILE,'P012.LSS'": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PANEL_SETUP, *SAV, STORE_PANEL, *RCL
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*RST (Reset)
Description
The *RST command initiates a device reset. *RST sets all traces to the GND line and recalls the factory
default panel setup (0).
Command Syntax
*RST
Example (GPIB)
The following instruction resets the oscilloscope:
CMD$="*RST": CALL IBWRT(SCOPE%,CMD$)
Related Commands
*CAL, *RCL
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*SAV (Save Setup)
Description
The *SAV command stores the current state of your instrument one of the non-volatile setup panels
(Setup 0 to Setup x). The *SAV command stores the complete setup of the oscilloscope at the time the
command is issued.
Note: The communication parameters (modified by commands CFMT, CHDR, CHLP, CORD and
WFSU) and the enable registers associated with the status reporting system (SRE, PRE, ESE, INE)
are not saved by this command.
Command Syntax
*SAV <panel_setup>
<panel_setup>:= 1 to x
1 to xare the corresponding setup panels available on your oscilloscope. The maximum value of xwill be
the highest number setup (e.g., 6 indicating Setup 6).
Example (GPIB)
The following instruction saves the current instrument setup in Setup 3:
CMD$="*SAV 3": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PANEL_SETUP, *RCL
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STORE_PANEL, STPN
Description
The STORE_PANEL command stores the complete panel setup of the oscilloscope in a file on the
instrument data drive (D:) or a connected mass storage device. The device and the file name are given as
two-value parameter pairs.
Note: The communication parameters (modified by commands CFMT, CHDR, CHLP, CORD and
WFSU) and the enable registers associated with the status reporting system (SRE, PRE, ESE, INE)
are not saved by this command.
If no file name (or an empty string) is supplied, the oscilloscope generates a file name according to its
internal rules. Autogenerated file names are numbered sequentially.
This command is the complement of RECALL_PANEL.
Command Syntax
STORE_PANEL DISK,<device>,FILE,'<filename>'
<device>:= {HDD, USB, MICRO}
<filename>:= full path to file
The file name string may be up to eight characters. Use the full path to the directory, including the drive
letter, enclosed in single quotes. Be sure there are no spaces before the directory string. The file extension
.LSS will be appended automatically.
Note: The hard drive selection (HDD) always points to drive D, which is the data drive on most
Teledyne LeCroy oscilloscopes. An external USB drive is usually named drive E; check your
oscilloscope file system. The device type MICRO applies only to instruments that utilize Micro-SD
card data storage, such as WaveSurfer 3000.
Example (GPIB)
The following instruction saves the current oscilloscope setup to USB drive in a file called DIODE.LSS:
CMD$="STPN DISK,USB,FILE,'DIODE.LSS'": CALL IBWRT(SCOPE%,CMD$)
Related Commands
PNSU, *SAV, RECALL_PANEL, *RCL
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STATUS Commands and Queries
ALL_STATUS?, ALST?
Description
The ALL_STATUS? query reads and clears the contents of all status registers: STB, ESR, INR, DDR, CMR,
EXR and URR except for the MAV bit (bit 6) of the STB register. For an interpretation of the contents of
each register, refer to the appropriate status register.
The query is useful to obtain a complete overview of the state of your oscilloscope.
Query Syntax
ALL_STATUS?
Response Format
ALL_STATUS STB,<n>,ESR,<n>,INR,<n>,DDR,<n>,CMR,<n>,EXR,<n>,URR,<n>
<n> : = 0 to 65535
Example
The following instruction reads the contents of all the status registers:
CMD$="ALST?": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD(SCOPE%,RSP$): PRINT RSP$
Response message:
ALST F2,000000,ESR,000052,INR,000005,DDR,000000,CMR,000004,EXR,000024,URR,000000
Related Commands
*CLS, CMR?, DDR?, *ESR?, EXR?, *STB?, URR?
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*CLS
Description
The *CLS command clears all status data registers.
Command Syntax
*CLS
Example (GPIB)
The following instruction causes all the status data registers to be cleared:
CMD$="*CLS": CALL IBWRT(SCOPE%,CMD$)
Related Commands
ALL_STATUS, CMR, DDR, *ESR, EXR, *STB, URR
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CMR?
Description
The CMR? query reads and clears the contents of the Command Error Register (refer to the following
table for details), which specifies the last syntax error type detected by your oscilloscope.
Query Syntax
CMR?
Response Format
CMR <code>
<code>:= 0 to 13
Example (GPIB)
The following instruction reads the contents of the CMR register:
CMD$="CMR?": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD(SCOPE%,RSP$): PRINT RSP$
Related Commands
ALL_STATUS?, *CLS
CMR (Command Error) Status Register Structure
Code Message
1 Unrecognized command/query header.
2 Illegal header path.
3 Illegal number.
4 Illegal number suffix.
5 Unrecognized keyword.
6 String error.
7 GET embedded in another message.
10 Arbitrary data block expected.
11 Non-digit character in byte count field of arbitrary data block.
12 EOI detected during definite length data block transfer.
13 Extra bytes detected during definite length data block transfer.
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DDR?
Description
The DDR? query reads and clears the contents of the Device Dependent or Device Specific Error Register
(DDR). In the case of a hardware failure, the DDR register specifies the origin of the failure.
Query Syntax
DDR?
Response Format
DDR <value>
<value>:= 0 to 65535
DDR (Device Dependent) Status Register Structure
Bit Value Meaning
15...14 Reserved.
13 8192 Timebase hardware failure detected.
12 4096 Trigger hardware failure detected.
11 2048 Channel 4 hardware failure detected.
10 1024 Channel 3 hardware failure detected.
9 512 Channel 2 hardware failure detected.
8 256 Channel 1 hardware failure detected.
7 128 External input overload condition detected.
6...4 Reserved.
3 8 Channel 4 overload condition detected.
2 4 Channel 3 overload condition detected.
1 2 Channel 2 overload condition detected.
0 1 Channel 1 overload condition detected.
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Part 6: IEEE 488.2 Command Reference
*ESE
Description
The *ESE command sets the standard Event Status Enable Register (ESE). This command allows one or
more events in the ESR register to be reflected in the ESB summary message bit (bit 5) of the STB
register. For an overview of the ESB defined events, refer to the ESR table.
The *ESE? query reads the contents of the ESE register.
Command Syntax
*ESE <value>
<value>:= 0 to 255
Query Syntax
*ESE?
Response Format
*ESE <value>
Example (GPIB)
The following instruction allows the ESB bit to be set if a user request (URQ bit 6, decimal 64) and/or a
device dependent error (DDE bit 3, decimal 8) occurs. Summing these values yields the ESE register mask
64+8=72.
CMD$="*ESE 72": CALL IBWRT(SCOPE%,CMD$)
Related Commands
*ESR
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*ESR?
Description
The *ESR? query reads and clears the contents of the Event Status Register (ESR). The response
represents the sum of the binary values of the register bits 0 to 7. The following table provides an overview
of the ESR register structure.
Query Syntax
*ESR?
Response Format
*ESR <value>
<value> : = 0 to 255
Example (GPIB)
The following instruction reads and clears the contents of the ESR register:
CMD$="*ESR?": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD(SCOPE%,RSP$): PRINT RSP$
Response message:
*ESR 0
Related Commands
ALL_STATUS, *CLS, *ESE
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Part 6: IEEE 488.2 Command Reference
ESR (Standard Events) Status Register Structure
Bit Value Name Meaning Notes
15...8 Reserved by IEEE 488.2.
7 128 PON Power Off-to-On occurred. The PON bit is always turned on (1) when the unit is
powered up.
6 64 URQ User request. On legacy LeCroy oscilloscopes, this bit reports
softkey inputs. It does not apply to MAUI oscilloscopes.
5 32 CME Command parser error detected. The CME bit is set true (1) whenever a command syn-
tax error is detected. The CME bit has an associated
Command Parser Register (CMR) which specifies the
error code. Refer to CMR?
4 16 EXE Execution error detected. The EXE bit is set true (1) when a command cannot be
executed due to some device condition (for example,
the oscilloscope in local state) or a semantic error. The
EXE bit has an associated Execution Error Register
(EXR) that specifies the error code. Refer to EXR?
3 8 DDE Device dependent error occurred. The DDE bit is set true (1) whenever a hardware fail-
ure has occurred at power-up or at execution time,
such as a channel overload condition, or a trigger or
timebase circuit defect. The origin of the failure can be
localized with the DDR? query.
2 4 QYE Query error occurred. The QYE bit is set true (1) whenever (a) an attempt is
made to read data from the Output Queue when no out-
put is either present or pending, (b) data in the Output
Queue has been lost, (c) both output and input buffers
are full (deadlock state), (d) an attempt is made by the
controller to read before having sent an <END>, (e) a
command is received before the response to the pre-
vious query was read (output buffer flushed).
1 2 RQC Requests bus control. The RQC bit is always false (0), as the oscilloscope
has no GPIB controlling capability and never requests
control.
0 1 OPC Operation complete. The OPC bit is set true (1) whenever *OPC has been
received, since commands and queries are strictly
executed in sequential order. The oscilloscope starts
processing a command only when the previous com-
mand has been entirely executed.
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EXR?
Description
The EXR? query reads and clears the contents of the Execution Error Register (EXR). The EXR register
specifies the type of the last error detected during execution. Refer to the following table for more
information.
Query Syntax
EXR?
Response Format
EXR? <code>
<code>:= 21 to 64
Example (GPIB)
The following instruction reads the contents of the EXR register:
CMD$="EXR?": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD(SCOPE%,RSP$): PRINT RSP$
Response message (if no fault):
EXR 0
Related Commands
ALL_STATUS, *CLS
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EXR (Execution Error) Status Register Structure
The following table lists the error codes that may be returned with the EXR query. Codes marked with an
asterisk (*) are valid only on instruments with a removable hard drive or memory card.
Code Description
21 Permission error. The command cannot be executed in local mode.
22 Environment error. The oscilloscope is not configured to correctly process a command. For instance, the oscil-
loscope cannot be set to RIS at a slow timebase.
23 Option error. The command applies to an option which has not been installed.
24 Unresolved parsing error.
25 Parameter error. Too many parameters specified.
26 Non-implemented command.
27 Parameter missing. A parameter was expected by the command.
30 Hex data error. A non-hexadecimal character has been detected in a hex data block.
31 Waveform error. The amount of data received does not correspond to descriptor indicators.
32 Waveform descriptor error. An invalid waveform descriptor has been detected.
33 Waveform text error. A corrupted waveform user text has been detected.
34 Waveform time error. Invalid RIS or TRIG time data has been detected.
35 Waveform data error. Invalid waveform data have been detected.
36 Panel setup error. An invalid panel setup data block has been detected.
50* No mass storage present when user attempted to access it.
51* Mass storage not formatted when user attempted to access it.
53* Mass storage was write protected when user attempted to create a file, to delete a file, or to format the device.
54* Bad mass storage detected during formatting.
55* Mass storage root directory full. Cannot add directory.
56* Mass storage full when user attempted to write to it.
57* Mass storage file sequence numbers exhausted (999 reached).
58* Mass storage file not found.
59* Requested directory not found.
61* Mass storage file name not DOS compatible, or illegal file name.
62* Cannot write on mass storage because file name already exists.
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INE
Description
The INE command sets the Internal State Change Enable register (INE). This command allows one or
more events in the INR register to be reflected in the INB summary message bit (bit 0) of the STB register.
For an overview of the INR defined events, refer to the Internal State Register Structure (INR) table in the
INR? topic for more information.
The INE? query reads the contents of the INE register.
Command Syntax
INE <value>
<value>:= 0 to 65535
Query Syntax
INE?
Response Format
INE <value>
Example (GPIB)
The following instruction allows the INB bit to be set whenever a screen dump has finished (bit 1, for
example decimal 2), or a waveform is acquired (bit 0, for example decimal 1), or both of these. Summing
these two values yields the INE mask 2+1=3.
CMD$="INE 3": CALL IBWRT(SCOPE%,CMD$)
Related Commands
INR?
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INR?
Description
The INR? query reads and clears the contents of the Internal State Change Register (INR). The INR
register (table below) records the completion of various internal operations and state transitions.
Query Syntax
INR?
Response Format
INR <state>
<state>:= 0 to 65535
Example (GPIB)
The following instruction reads the contents of the INR register:
CMD$="INR?": CALL IBWRT(SCOPE%,CMD$)
The response message represents the summed bit value of the internal state changes:
INR 1026
Meaning, waveform processing in math function F3 (1024) and a screen dump (2) have both terminated.
Related Commands
ALL_STATUS, *CLS, INE
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INR? (Internal State Change) Status Register Structure
The following table describes the states corresponding to the returned bit values:
Bit Value State
15 0 - Reserved for future use.
14 16384 1 - Probe was changed.
13 8192 1 - Trigger is ready.
12 4096 1 - Pass/Fail test detected desired outcome.
11 2048 1 - Waveform processing has terminated in trace F4.
10 1024 1 - Waveform processing has terminated in trace F3.
9 512 1 - Waveform processing has terminated in trace F2.
8 256 1 - Waveform processing has terminated in trace F1.
7 128 1 - A floppy or hard disk exchange has been detected.
6 64 1 - Floppy or hard disk has become full in AutoStore Fill mode.
5 32 0 - Reserved for LeCroy use.
4 16 1 - A segment of a sequence waveform has been acquired in acquisition memory but not yet read
out into the main memory.
3 8 1 - A time-out has occurred in a data block transfer.
2 4 1 - A return to the local state is detected.
1 2 1 - A screen dump has terminated.
0 1 1 - A new signal has been acquired in acquisition memory and read out into the main memory.
Note: On Teledyne LeCroy oscilloscopes, INR status bit 13 is set high when a trigger is armed, even
though the oscilloscope may not yet be ready to acquire due to technical limitations. If you are
concerned with timing a second action on the Trigger Ready state, it is safest to use the result of
the command TRMD SINGLE; WAIT;*OPC?, which will be 1 when the previous acquisition is fully
complete.
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Part 6: IEEE 488.2 Command Reference
*IST?
Description
The *IST? (Individual STatus) query reads the current state of the IEEE 488.1-defined IST local message.
The IST individual status message is the status bit sent during a parallel poll operation.
Query Syntax
*IST?
Response Format
*IST <value>
<value>:= 0 or 1
Example (GPIB)
The following instruction causes the contents of the IST bit to be read:
CMD$="*IST?": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD(SCOPE%,RSP$): PRINT RSP$
Response message:
*IST 0
Related Commands
*PRE
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*OPC
Description
The *OPC (Operation Complete) command sets the OPC bit (bit 0) to "true" in the standard Event Status
Register (ESR).
The *OPC? query always responds with the ASCII character 1 because the oscilloscope only responds to
the query when the previous commands are entirely executed. Since *OPC? executes only when
processing is complete, it is recommended for synchronization purposes. See Timing and
Synchronization.
Command Syntax
*OPC
Query Syntax
*OPC?
Response Format
1
Related Commands
*WAI
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Part 6: IEEE 488.2 Command Reference
*PRE
Description
The *PRE command sets the PaRallel poll Enable register (PRE). The lowest eight bits of the Parallel Poll
Register (PPR) are composed of the STB bits. *PRE allows you to specify which bit(s) of the parallel poll
register affect the IST (Individual Status Bit).
The *PRE? query reads the contents of the PRE register. The response is a decimal number corresponding
to the binary sum of the register bits.
Command Syntax
PRE <value>
<value>:= 0 to 65535
Query Syntax
*PRE?
Response Format
*PRE <value>
Example (GPIB)
The following instruction causes the IST status bit to become 1 as soon as the MAV bit (bit 4 of STB,
meaning decimal 16) is set, and yields the PRE value 16:
CMD$="*PRE 16": CALL IBWRT(SCOPE%,CMD$)
Related Commands
*IST
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*SRE
Description
The *SRE command sets the Service Request Enable register (SRE). This command allows you to specify
which summary message bit or bits in the STB register generate a service request. Refer to the table on
page 225 for an overview of the available summary messages.
A summary message bit is enabled by writing a 1 into the corresponding bit location. Conversely, writing a
0 into a given bit location prevents the associated event from generating a service request (SRQ). Clearing
the SRE register disables SRQ interrupts.
The *SRE? query returns a value that, when converted to a binary number, represents the bit settings of
the SRE register. Note that bit 6 (MSS) cannot be set and its returned value is always zero.
Command Syntax
*SRE <value>
<value>:= 0 to 255
Query Syntax
*SRE?
Response Format
*SRE <value>
Example (GPIB)
The following instruction allows an SRQ to be generated as soon as the MAV summary bit (bit 4, for
example decimal 16) or the INB summary bit (bit 0, for example decimal 1) in the STB register, or both, are
set. Summing these two values yields the SRE mask 16 + 1 = 17.
CMD$="*SRE 17": CALL IBWRT(SCOPE%,CMD$)
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Part 6: IEEE 488.2 Command Reference
*STB?
Description
The *STB? query reads the contents of the 488.1 defined Status Byte Register (STB) and Master
Summary Status (MSS). The response represents the values of bits 0 to 5 and 7 of the STB register and
the MSS summary message.
The response to a *STB? query is identical to the response of a serial poll except that the MSS summary
message appears in bit 6 in place of the RQS message.
Query Syntax
*STB?
Response Format
*STB? <value>
<value>:= 0 to 255
Example (GPIB)
The following instruction reads the Status Byte Register:
CMD$="*STB?": CALL IBWRT(SCOPE%,CMD$):
CALL IBRD(SCOPE%,RSP$): PRINT RSP$
Response message:
*STB 0
Related Commands
ALL_STATUS, *CLS, *PRE, *SRE
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STB (Status Byte) Status Register Structure
Bit Value Name Description Notes
7 128 DIO7 Reserved for
future use.
6 64 MSS/RQS
MSS = 1
RQS = 1
At least 1 bit in
STB masked by
SRE is 1, service
is requested.
The Master Summary Status (MSS) indicates the oscilloscope requests
service, while the Service Request status (when set) specifies the
oscilloscope issued a service request. Bit position 6 depends on the
polling method:
MSS if an *STB? query is received
RQS if serial polling is conducted
Example:
If SRE = 10 and STB = 10, then MSS = 1.
If SRE = 010 and STB = 100 then MSS = 0.
5 32 ESB An ESR enabled
event has
occurred.
The Event Status Bit (ESB) indicates whether or not one or more of the
enabled IEEE 488.2 events occurred since the last reading or clearing of
the Standard Event Status Register (ESR). ESB is set if an enabled event
becomes true (1).
4 16 MAV Output queue is
not empty.
The Message AVailable bit (MAV) indicates whether or not the Output
queue is empty. The MAV summary bit is set true (1) whenever a data byte
resides in the Output queue.
3 8 DIO3 Reserved.
2 4 VAB A command data
value has been
adapted.
The Value Adapted Bit (VAB) is set true (1) whenever a data value in a
command is adapted to the nearest legal value. For instance, the VAB bit
would be set if the timebase is redefined as 2.5 µs/div since the adapted
value is 2 µs/div.
1 2 DIO1 Reserved.
0 1 INB An enabled
internal state
change occurred.
The Internal State Bit (INB) is set true (1) whenever certain enabled internal
states are entered. For further information, refer to the INR? query.
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Part 6: IEEE 488.2 Command Reference
*WAI
Description
The *WAI (Wait to continue) command, required by the IEEE 488.2 standard, has no effect on the
oscilloscope, as the instrument only starts processing a command when the previous command has been
entirely executed.
Command Syntax
*WAI
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STORAGE Commands and Queries
DELETE_FILE, DELF
Description
The DELETE_FILE command deletes a file from the currently selected directory.
Command Syntax
DELETE_FILE DISK,<medium>,FILE,'<filename>'
<medium>: = {HDD, USB, MICRO}
The file name must be enclosed in single quotes. Use the full path to the directory, including the drive
letter. Be sure there are no spaces before the directory string.
Note: The hard drive selection (HDD) always points to drive D, which is the data drive on MAUI
oscilloscopes. An external USB drive is usually named drive E; check your oscilloscope file system.
The device type MICRO applies only to instruments that utilize Micro-SD card data storage, such
as WaveSurfer 3000.
Example (GPIB)
The following instruction deletes a panel setup file from the hard drive:
CMD$="DELF DISK,HDD,FILE,'D:\SETUPS\TESTRUN.LSS'
CALL IBWRT(SCOPE%,CMD$)
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Part 6: IEEE 488.2 Command Reference
TRANSFER_FILE, TRFL
Description
This command allows you to transfer files to and from storage media, or between oscilloscope and
computer. The command format is used to transfer files from the computer to storage media. The query
format is used to transfer files from storage media to computer.
Command Syntax
TRANSFER_FILE DISK,<device>,FILE,'<filepath>',#9<nnnnnnnnn><data><crc>
<device>:={HDD, USB, MICRO}
<filepath>:= legal DOS path to file
<nnnnnnnnn>:= file size in bytes (<data> size + <crc> size)
<data>:= file data (arbitrary data block)
<crc>:= reserved for 32-bit CRC plus 8-byte CRC trailer
The path name must be enclosed in single quotes. Use the full path to the directory, including the drive
letter. Be sure there are no spaces before the directory string.
Note: The hard drive selection (HDD) always points to drive D, which is the data drive on MAUI
oscilloscopes. An external USB drive is usually named drive E; check your oscilloscope file system.
The device type MICRO applies only to instruments that utilize Micro-SD card data storage, such
as WaveSurfer 3000.
Note: CRC checking is not performed by the scope, however the 8-byte CRC trailer string is
required when sending a file to the scope, and supplied when receiving a file from the scope. The
ASCII string 'ffffffff' is normally used as trailer string.
Query Syntax
TRFL? DISK,<device>,FILE,'<filepath>'
Response Format
TRFL #9nnnnnnnnn<data><crc>
Example (GPIB)
The following instruction reads the file FAVORITE.DSO from the hard drive:
CMD$=TRFL DISK,HDD,FILE,'FAVORITE.DSO' CALL IBWRT(SCOPE%,CMD$)
Related Commands
DIRECTORY
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WAVEFORM TRANSFER Commands and Queries
INSPECT?, INSP?
Description
The INSPECT? query allows you to read parts of an acquired waveform in intelligible form. The command
is based on the explanation of the format of a waveform given by the Waveform Template (use the
TEMPLATE? query to obtain an up-to-date copy of the template).
Any logical block of a waveform can be inspected using this query by giving its name enclosed in quotes as
the first parameter (refer to the template itself for more details).
The special logical block named WAVEDESC can also be inspected in more detail. By giving the name of a
variable in the WAVEDESC block as the first parameter, it is possible to inspect only the value of that one
entity.
Query Syntax
<trace>:INSPECT? '<WAVEDESC variable|logical block>',[<data_type>]
<trace>:= C1 to Cx, F1 to Fx, M1 to Mx, TA to TD
<WAVEDESC_variable>:= any variable listed in the WAVEDESC block of the
oscilloscope's Waveform Template
<logical_block>:= {TRIGTIME,RISTIME,SIMPLE,DATA_ARRAY_1,DATA_ARRAY_2,
<data_type>:= {BYTE, WORD, FLOAT}
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
You may use single or double quotation marks in the query, but the reply always uses double quotes.
The optional parameter <data_type> applies only to inspection of data arrays. It selects the representation
of the data. The default <data_type> is FLOAT.
Data Type Descriptions
BYTE Raw data as integers (truncated to 8 most significant bits).
FLOAT Normalized data (gain, offset applied) as floating point numbers (gives measured values in volts or units).
WORD Raw data as integers (truncated to 16 most significant bits).
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Block WAVEDESC contains several variables related to scaling of data values. Values of these variables
depend on the current setting of the command COMM_FORMAT (CFMT). The following example shows
how the values returned by INSP? change when you modify the CFMT setting from BYTE (default) to
WORD:
CFMTSet to BYTE CFMT Set to WORD
VERTICAL_GAIN : 3.1250e-003
VERTICAL_OFFSET : -2.0600e-001
MAX_VALUE : 1.2700e+002
MIN_VALUE : -1.2800e+002
VERTICAL_GAIN : 1.2207e-005
VERTICAL_OFFSET : -2.0600e-001
MAX_VALUE : 3.2512e+004
MIN_VALUE : -3.2768e+004
Response Format
<trace>:INSPECT "<WAVEDESC_variable|logical_block>: <value>"
Examples (GPIB)
The following instruction reads the value of the timebase at which the last waveform in Channel 1 was
acquired:
CMD$="C1:INSP? 'TIMEBASE'"
CALL IBWRT(SCOPE%,CMD$)
CALL IBRD(SCOPE%,RSP$)
PRINT RSP$
Response message:
C1:INSP "TIMEBASE: 500 US/DIV"
The following instruction reads the entire contents of the waveform descriptor block:
CMD$="C1:INSP? 'WAVEDESC'"
Related Commands
COMM_FORMAT, TEMPLATE, WAVEFORM_SETUP
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RECALL, REC
Description
The RECALL command recalls a waveform file from the current directory on mass storage into any of the
internal memories (M1 to Mx).
Only waveforms stored in binary format (.trc) can be recalled.
Command Syntax
<memory>:RECALL DISK,<device>,FILE,'<file name>'
<device>:= {HDD, USB, MICRO}
<memory>:= M1 to Mx
<file name>:= full path to .trc file
The file path must be enclosed in single quotes. Use the full path to the directory, including the drive letter.
Be sure there are no spaces before the directory string.
Note: The hard drive selection (HDD) always points to drive D, which is the data drive on MAUI
oscilloscopes. An external USB drive is usually named drive E; check your oscilloscope file system.
The device type MICRO applies only to instruments that utilize Micro-SD card data storage, such
as WaveSurfer 3000.
Example (GPIB)
The following instruction recalls the waveform file 'C2Trace00000.trc' into Memory 1:
CMD$="<M1:REC DISK,HDD,FILE,'D:\Waveforms\C2Trace00000.trc'": CALL IBWRT
(SCOPE%,CMD$)
Related Commands
STORE, INR?
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Part 6: IEEE 488.2 Command Reference
STORE, STO
Description
The STORE command stores the contents of the specified trace in one of the internal memories M1 to M4
or in the current directory in mass storage. The files are saved in binary with the .trc extension.
The complement to the STORE command is the RECALL command, which recalls waveforms saved to
external files into one of the oscilloscope internal memories.
Set the current directory (where files are stored) with the DIR command.
Command Syntax
STORE [<trace>,<dest>]
<trace>:= C1 to Cx, F1 to Fx, TA to TD, or ALL_DISPLAYED
<dest>:= M1 to Mx, or FILE
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
When storing traces to FILE, files are saved with the .trc extension in the directory last set with the DIR
command. File names are autogenerated.
If you send the STORE command without an argument, the current Storage Setup operation will be
stored. Modify this setup using STORE_SETUP.
Example (GPIB)
The following instruction stores the Channel 4 (C4) waveform into Memory 1 (M1):
CMD$="STO C4,M1": CALL IBWRT(SCOPE%,CMD$)
The following instruction stores all currently displayed waveforms onto the hard drive:
CMD$="STO ALL_DISPLAYED,FILE": CALL IBWRT(SCOPE%,CMD$)
The following instruction executes the storage operation currently defined in the Storage Setup:
CMD$="STO": CALL IBWRT(SCOPE%,CMD$)
Related Commands
DIR, RECALL, STORE_SETUP
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STORE_SETUP, STST
Description
The STORE_SETUP command controls the way in which traces are stored. Any one trace or all displayed
traces can be set up for storage, either by turning on AUTO store or using the STORE command.
Two modes are available when using AUTO store: FILL, which stops when the storage medium is full, and
WRAP, which replaces the oldest trace by the latest one. Wrap mode overwrites any trace file, whether or
not it was made during the current session or records the same trace.
Command Syntax
STORE_SETUP [<trace>,<dest>][,AUTO,<mode>][,FORMAT,<type>]
<trace>:= C1 to Cx, F1 to Fx, M1 to Mx, TA to TD, ALL_DISPLAYED
<dest>:= M1 to Mx, HDD
<mode>:= {OFF, FILL, WRAP}
<type>:= {ASCII, BINARY, EXCEL,MATHCAD, MATLAB}
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
Query Syntax
STORE_SETUP?
Response Format
STORE_SETUP <trace>,<dest>,AUTO,<mode>
Example (GPIB)
The following instruction enables AUTO store for Channel 1, to be performed until insufficient space
remains for another file.
CMD$="STST C1,HDD,AUTO,FILL" CALL IBWRT("SCOPE%", CMD$)
Related Commands
STORE, INR
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Part 6: IEEE 488.2 Command Reference
TEMPLATE?, TMPL?
Description
The TEMPLATE? query produces a copy of the template that describes the various logical entities making
up a complete waveform. In particular, the template describes in full detail the variables contained in the
descriptor part of a waveform.
Query Syntax
TEMPLATE?
Response Format
TEMPLATE? "<template>"
<template>:= Variable length string detailing the structure of a waveform.
Related Commands
INSPECT?
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WAVEFORM, WF
Description
A WAVEFORM command transfers a waveform from the controller to the oscilloscope, whereas a
WAVEFORM? query transfers a waveform from the oscilloscope to the controller.
WAVEFORM stores an external waveform back into the oscilloscope's internal memory. A waveform
consists of several distinct entities:
lThe waveform descriptor (DESC)
lThe user text (TEXT)
lThe time descriptor (TIME)
lThe data block (DAT1)
lAn optional second data block (DAT2)
The WAVEFORM? query instructs the oscilloscope to transmit a waveform to the controller. The entities
can be queried independently. If the ALL parameter is specified, all four or five entities are transmitted in
one block in the order shown above.
Note: Only complete waveforms transmitted with the WAVEFORM? ALL query can be restored to
the oscilloscope.
The format of the waveform data depends on the current settings specified by the last WAVEFORM_
SETUP, COMM_ORDER and COMM_FORMAT commands.
Command Syntax
<memory>:WAVEFORM ALL <waveform_data_block>
<memory>:= M1 to Mx
<waveform_data_block>:= arbitrary data block
Query Syntax
<trace>:WaveForm? <block>
<trace>:= C1 to Cx, F1 to Fx, M1 to Mx, TA to TD
<block>:= {DESC, TEXT, TIME, DAT1, DAT2, ALL}
Note: TA through TD are for backward compatibility. Although accepted, they are not returned by
queries.
If you do not provide a <block> parameter, ALL is assumed.
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Part 6: IEEE 488.2 Command Reference
Response Format
<trace>:WAVEFORM <block>,<waveform_data_block>
Tip: It may be convenient to disable the response header if the waveform is to be restored to the
oscilloscope. See the COMM_HEADER topic for more information.
Examples (GPIB)
The following instruction reads the block DAT1 from Memory 1 and saves it in the file "MEM1.DAT". The
path header "M1:" is saved together with the data.
FILE$ = "MEM1.DAT"
CMD$ = "M1:WF? DAT1"
CALL IBWRT(SCOPE%,CMD$)
CALL IBRDF(SCOPE%,FILE$)
In the following example, the entire contents of Channel 1 are saved in the file "CHAN1.DAT". The path
header "C1:" is skipped to ensure that the data can later be recalled into the oscilloscope.
FILE$="CHAN1.DAT":RD$=SPACE$(3)
CMD$="CHDR SHORT; C1:WF?"
CALL IBWRT(SCOPE%,CMD$)
CALL IBRD(SCOPE%,RD$) ' Skip first 3 characters "C1:"
CALL IBRDF(SCOPE%,FILE$) ' Save data in file "CHAN1.DAT"
The following instruction illustrates how the waveform data saved in the preceding example can be
recalled into Memory 1:
FILE$ = "CHAN1.DAT"
CMD$ ="M1:"
CALL IBEOT(SCOPE%,0) ' disable EOI
CALL IBWRT(SCOPE%,CMD$)
CALL IBEOT(SCOPE%,1) ' re-enable EOI
CALL IBWRTF(SCOPE%,FILE$)
The "M1:" command ensures the active waveform is "M1". When the data file is sent to the oscilloscope, it
first sees the header "WF" (the characters "C1:" having been skipped when reading the file) and assumes
the default destination "M1".
Related Commands
INSPECT, COMM_FORMAT, COMM_ORDER, FUNCTION_STATE, TEMPLATE, WAVEFORM_SETUP,
WAVEFORM_TEXT
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WAVEFORM_SETUP, WFSU
Description
The WAVEFORM_SETUP command specifies the amount of data in a waveform to be transmitted to the
controller.
The WAVEFORM_SETUP? query returns the transfer parameters currently in use.
Command Syntax
WAVEFORM_SETUP SP,<sparsing>,NP,<number>,FP,<first point>,SN,<segment>
Note: After power-on, all values are set to 0 (meaning, entire waveforms are transmitted without
sparsing). Parameters are grouped in pairs. The first of the pair names which variable is modified,
while the second provides the new value for assignment. Pairs can be given in any order and
restricted to the variables for change.
Sparsing (SP)
The sparsing parameter defines the interval between data points. For example:
SP = 0 sends all data points.
SP = 1 sends all data points.
SP = 4 sends every 4th data point.
Number of Points (NP)
The number of points parameter indicates how many points should be transmitted. For example:
NP = 0 sends all data points.
NP = 1 sends 1 data point.
NP = 50 sends a maximum of 50 data points.
NP = 1001 sends a maximum of 1001 data points.
First Point (FP)
The first point parameter specifies the address of the first data point to be sent. For waveforms acquired
in sequence mode, this refers to the relative address in the given segment. For example:
FP = 0 corresponds to the first data point.
FP = 1 corresponds to the second data point.
FP = 5000 corresponds to data point 5001.
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Segment Number (SN)
The segment number parameter indicates which segment should be sent if the waveform was acquired in
sequence mode. This parameter is ignored for non-segmented waveforms. For example:
SN = 0 all segments.
SN = 1 first segment.
SN = 23 segment 23.
Query Syntax
WAVEFORM_SETUP?
Response Format
WAVEFORM_SETUP SP,<sparsing>,NP,<number>,FP,<first point>,SN,<segment>
Example (GPIB)
The following instructs every 3rd data point (SP = 3) starting at address 200 for transfer:
CMD$="WFSU SP,3,FP,200": CALL IBWRT(SCOPE%,CMD$)
Related Commands
INSPECT, WAVEFORM, TEMPLATE
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DISK DRIVE ANALYSIS (Option) Commands and Queries
DD_ANALOG_COMP_THRESH, DACT
Description
Sets the analog threshold value for Analog Compare.
Command Syntax
DD_ANALOG_COMPARE_THRESHOLD <threshold>
<threshold >:= float in range 0.0 to 1.0. Analog Compare error threshold in units of
full-scale error.
Query Syntax
DD_ANALOG_COMPARE_THRESHOLD?
Response Format
DD_ANALOG_COMPARE_THRESHOLD <threshold>
Related Commands
DD_FIND_ERROR, DD_FIND_METHOD
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DD_ANALYZE_REGION_DISABLE, DARD
Description
Disables the use of the analyze region markers, which means the entire waveform will be analyzed in
analog compare and channel emulation.
Command Syntax
DD_ANALYZE_REGION_DISABLE
The analyze region is enabled whenever DD_ANALYZE_REGION_START or DD_ANALYZE_REGION_
LENGTH are set.
Related Commands
DD_ANALYZE_REGION_START, DD_ANALYZE_REGION_LENGTH
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DD_ANALYZE_REGION_LENGTH, DARL
Description
Selects the length of a region to be analyzed.
Command Syntax
DD_ANALYZE_REGION_LENGTH <time >
<time>:= time in seconds
Query Syntax
DD_ANALYZE_REGION_LENGTH?
Response Format
DD_ANALYZE_REGION_LENGTH <time >
Related Commands
DD_ANALYZE_REGION_START, DD_ANALYZE_REGION_DISABLE
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DD_ANALYZE_REGION_START, DARS
Description
Selects the start of a region to be analyzed.
Command Syntax
DD_ANALYZE_REGION_START <time >
<time>:= time in seconds
Query Syntax
DD_ANALYZE_REGION_START?
Response Format
DD_ANALYZE_REGION_START <time >
Related Commands
DD_ANALYZE_REGION_LENGTH, DD_ANALYZE_REGION_DISABLE
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DD_BITCELL, DBIT
Description
Enters the bit cell time of the head signal.
Command Syntax
DD_BITCELL <bittime>
<bittime>:= time in range 0.10–99.99 ns
Query Syntax
DD_BITCELL?
Response Format
DD_BITCELL <bittime>
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DD_BYTE_OFFSET, DBYT
Description
Moves the head trace to show the specified byte. Channel must be configured.
Command Syntax
DD_BYTE_OFFSET <bytenum>
<bytenum>:= integer in range 20 to 50,000
Query Syntax
DD_BYTE_OFFSET?
Response Format
DD_BYTE_OFFSET <bytenum>
Related Commands
DD_BYTE_OFFSET, DD_VCOSYNCH_TO_DATA, DD_BITCELL, DD_ENCODING, DD_SIGNAL_INPUT
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DD_BYTE_OFFSET_SEGMENT, DSEG
Description
Moves the head trace to show the specified segment.
Command Syntax
DD_BYTE_OFFSET _SEGMENT <segnum>
<segnum>:= integer in range 1 to 999
Query Syntax
DD_BYTE_OFFSET _SEGMENT?
Response Format
DD_BYTE_OFFSET _SEGMENT <segnum>
Related Commands
DD_BYTE_OFFSET
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DD_CTAF_3DB, D3D
Description
Sets the CTAF (Continuous Time Analog Filter) parameter, 3 dB.
Command Syntax
DD_CTAF_3DB <3 dB point>
<3 dB point>:= frequency in range 0.1 to 1.0 * sampling frequency
Query Syntax
DD_CTAF_3DB?
Response Format
DD_CTAF_3DB <3 dB point>
Related Commands
DD_CTAF_FC, DD_CTAF_BOOST, DD_CTAF_GROUP_DELAY, DD_TRAIN_FILTER
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DD_CTAF_BOOST, DBST
Description
Sets the CTAF (Continuous Time Analog Filter) parameter, boost.
Command Syntax
DD_CTAF_BOOST <boost>
<boost>:= gain (in dB) in range 0.0–13.0 dB
Query Syntax
DD_CTAF_BOOST?
Response Format
DD_CTAF_BOOST <boost>
Related Commands
DD_CTAF_FC, DD_CTAF_3DB, DD_CTAF_GROUP_DELAY, DD_TRAIN_FILTER
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DD_CTAF_FC, DDFC
Description
Sets the CTAF (Continuous Time Analog Filter) parameter, cut-off frequency fc.
Command Syntax
DD_CTAF_FC <fc>
<fc>:= frequency in range 0.1 to 1.0 * sampling freq.
Query Syntax
DD_CTAF_FC?
Response Format
DD_CTAF_FC <fc>
Related Commands
DD_CTAF_3DB, DD_CTAF_BOOST, DD_CTAF_GROUP_DELAY, DD_TRAIN_FILTER
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DD_CTAF_GROUP_DELAY, DFGD
Description
Sets the CTAF (Continuous Time Analog Filter) parameter, group delay.
Command Syntax
DD_CTAF_GROUP_DELAY <gdpercent>
<gdpercent>:= value in range -30.0% to +30.0%
Query Syntax
DD_CTAF_GROUP_DELAY?
Response Format
DD_CTAF_GROUP_DELAY <gdpercent>
Related Commands
DD_TRAIN_FILTER, DD_CTAF_FC DD_CTAF_3DB, DD_CTAF_BOOST
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DD_ENCODING, DENC
Description
Allows selection of the data-encoding ratio for locating the bytes by byte offset.
Command Syntax
DD_ENCODING <m>,<n>
<m>:= integer in range 1 to 32
<n>:= integer in range <m> to 32
Query Syntax
DD_ENCODING?
Response Format
DD_ENCODING <m>,<n>
Related Commands
DD_BYTE_OFFSET
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DD_ERR_INFO?, DERI?
Description
Returns the measured value associated with the last error position selected, and a code specifying what
the value contains.
Query Syntax
DD_ERR_INFO?
Response Format
Shown with short header, the default query response state:
DERI <code>,<value>
The first number is the code, the second is the value. The meaning of the code is:
0 = invalid, never selected an error position yet
1 = SAM from channel emulation without reference(always greater than 0)
2 = Run Length Limit violation from channel emulation, the value is the number of bit cells without a
magnetic transition.
3 = Analog Distance (normalized, proportional to Volts squared) from analog compare
4 = SAM from channel emulation with reference (can be negative, if a different path should have been
taken)
Example
DERI? might return "DERI 1,1.7683".
Related Commands
DD_NUM_ERRORS, DD_FIND_ERRO, DD_ERR_NUM
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Part 6: IEEE 488.2 Command Reference
DD_ERR_NUM, DERR
Description
Displays the section of waveform containing the specified error number.
Command Syntax
DD_ERR_NUM <errnum>
<errnum>:= integer in range 1 to #errors found
If there are no errors, any invocation produces error status. An <errnum> greater than #errors found
produces an error.
Related Commands
DD_FIND_ERROR, DD_ERR_INFO,DD_NUM_ERRORS
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DD_FIND_BITCELL?, DFBIT?
Description
Looks at the head signal and attempts to determine the bit-cell time. To be successful, the user must have
positioned the Analyze Region Start cursor inside the synch field or have read gate setup.
Query Syntax
DD_FIND_BITCELL?
Response Format
DD_FIND_BITCELL <bool>
<bool>:= {0, 1}
1 if successful; 0 if not successful.
Related Commands
DD_ANALYZE_REGION_START, DD_ANALYZE_REGION_LENGTH, DD_BITCELL, DD_VCO_SYNCH_
PATTERN
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DD_FIND_ERROR, DFER
Description
Commands the DDA to find errors.
Command Syntax
DD_FIND_ERROR <bool>
<bool>:= {OFF, ON}
Query Syntax
DD_FIND_ERROR?
Response Format
DD_FIND_ERROR <bool>
Related Commands
DD_FIND_METHOD
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DD_FIND_METHOD, DDFM
Description
Selects the error-finding method.
Command Syntax
DD_FIND_METHOD <method>
<method>:= {ANALOG_COMPARE, ML_DISTANCE, ML_COMPARE}
ML_DISTANCE emulates a PRML channel without a reference signal, whereas ML_COMPARE uses a
reference.
Query Syntax
DD_FIND_METHOD?
Response Format
DD_FIND_METHOD <method>
Related Commands
DD_FIND_ERROR, DD_SAM_THRESH, DD_ANALOG_COMP_THRESH
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DD_FIR, DFIR
Description
Stores the setup that will be used if the FIR filter is enabled for use in the channel emulation.
Command Syntax
DD_FIR <num>,<coef_0>,<coef_1>,<coef_2>,.....,<coef_n+1>
Query Syntax
DD_FIR?
Response Format
DD_FIR <num>,<coef_0>,<coef_1>,<coef_2>,.....,<coef_n+1>
Where <num> can be 1 to 21. The sum of the coefficients must be greater than 0.1. If the sum of the
coefficients is greater than 1.0, the coefficients will be scaled so that they sum to 1.0.
Related Commands
DD_FIR_ENABLE
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DD_FIR_ENABLE, DFEN
Description
Enable/disables the FIR filter for PRML channel emulation. It is always possible to disable the FIR.
Requests to enable the FIR only succeed if the following conditions are true:
lNumber of coefficients is > 0 and < 21
lAt least one of the coefficients is non-zero
These conditions will be met if the DD_FIR command was ever executed successfully. The setup
established by DD_FIR is not affected by DD_FIR_ENABLE: the FIR filter may be enabled and disabled
without having to reestablish the setup.
Command Syntax
DD_FIR_ENABLE <bool>
<bool>:= {YES, NO}
Query Syntax
DD_FIR_ENABLE?
Response Format
DD_FIR_ENABLE <bool>
Related Commands
DD_FIR
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Part 6: IEEE 488.2 Command Reference
DD_HEADSIGNAL_CHANNEL, DHSC
Description
Specifies the head signal source channel or memory for channel emulation and servo analysis.
Command Syntax
DD_HEADSIGNAL_CHANNEL <channel>
<channel>:= {NONE, C1 to Cx, M1 to Mx}
Query Syntax
DD_HEADSIGNAL_CHANNEL?
Response Format
DD_HEADSIGNAL_CHANNEL <channel>
Related Commands
DD_SIGNAL_INPUT
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DD_IGNORE_SAMPLES, DIGS
Description
Defines the number of samplesto be ignored at the Read Gate signal end for channel emulation and
analog compare.
Command Syntax
DD_IGNORE_SAMPLES <samples>
<samples>:= integer in range 0 to 999.
Query Syntax
DD_IGNORE_SAMPLES?
Response Format
DD_IGNORE_SAMPLES <samples>
Related Commands
DD_READGATE_CHANNEL
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Part 6: IEEE 488.2 Command Reference
DD_ML_MIN_SPACING, DRLM
Description
When channel emulation is active, this sets the minimum allowed spacing of transitions. Minimum allowed
spacing of transitions affects PR4, EPR4 and E2PR4.
Command Syntax
DD_ML_MIN_SPACING <d>
<d>:= integer in range 0 to 2
0 means adjacent transitions are allowed; 1 means there must be at least one non-transition between
each transition; 2 is only valid for E2PR4.
Query Syntax
DD_ML_MIN_SPACING?
Response Format
DD_ML_MIN_SPACING <d>
Related Commands
DD_FIND_ERROR, DD_ML_RUN_LENGTH_LIMIT
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DD_ML_RUN_LENGTH_LIMIT, DRLE
Description
Limits the run length, the number of “0” values in a row for the head/analog signal when channel emulation
is active.
Command Syntax
DD_ML_RUN_LENGTH_LIMIT <k>
<k>:= integer in the range 0 to 99.
Maximum allowed run of non-transitions. If zero, then RLL checking is disabled.
Query Syntax
DD_ML_RUN_LENGTH_LIMIT?
Response Format
DD_ML_RUN_LENGTH_LIMIT <k>
Related Commands
DD_FIND_ERROR, DD_ML_MIN_SPACING
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DD_NUM_ERRORS?, DNER?
Description
Returns the number of errors found.
Query Syntax
DD_NUM_ERRORS?
Response Format
DD_NUM_ERRORS <errorcount>
<errorcount>: = number of errors found
Related Commands
DD_FIND_EROR, DD_ERR_NUM, DD_ERR_INFO, DD_NUM_ERRORS
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DD_OVERLAP_REF, DOVL
Description
This command sets a state variable which determines whether Byte Offset (when jumping to a "Worst
SAM #" or an NRZ mismatch position) or other disk-drive related features re-establish the overlap of the
reference signal whenever they move the head trace. To re-establish overlap, they calculate correlation
over a window around the expected match position, and overlap the waveform at the sample where the
correlation is highest. The size of the window is limited to the width of the head trace display or to a fixed
number of bytes, whichever is smaller. If the waveform is greatly different within the window, the most
correlated position may not be meaningful, and the waveforms will not appear overlapped. This should be
clear on the display.
The command DD_OVERLAP_REF ON does not cause the reference to be displayed. The next change of
Byte Offset, etc, causes the reference to be displayed, correctly overlapped.
The command DD_OVERLAP_REF OFF does not cause the reference trace to be turned off. It may be
turned off, or repositioned as desired by the user. Subsequent changes to Byte Offset, etc, do not move
the reference and do not cause it to be displayed.
Command Syntax
DD_OVERLAP_REF <bool>
<bool>: = {OFF, ON}
Query Syntax
DD_OVERLAP_REF?
Response Format
DD_OVERLAP_REF <bool>
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Part 6: IEEE 488.2 Command Reference
DD_PES_ANALYSIS, DPA
Description
Starts or aborts PES analysis. The query returns status of the analysis.
Command Syntax
DD_PES_ANALYSIS <command>
<command>:= {START, ABORT}
Query Syntax
DD_PES_ANALYSIS?
Response Format
DD_PES_ANALYSIS <state>
<state>:= 1 = running, 0 = stopped
Related Commands
DD_PES_DATA, DD_PES_SETUP
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DD_PES_DATA?, DPD?
Description
Reads out results of PES Analysis.
Query Syntax
DD_PES_DATA? [<sort order>]
<sort_order>:= {WEDGE, RRO, IRO, MAX, MIN, SIGMA}
<sort_order> is an optional parameter that specifies how data is sorted on output. Data can be sorted by:
WEDGE, RRO (Repetitive Runout), IRO (Instantaneous Runout), MAX (Maximum Runout), MIN (Minimum
Runout), or SIGMA (Runout Standard Deviation).
Response Format
DD_PES_DATA? “<wedge_1>,<IRO_1>,<RRO_1>,<MAX_1>,<MIN_1>,<SIGMA_1>,…,<wedge_N>,…”
Related Commands
DD_PES_ANALYSIS, DD_PES_SETUP, DD_PES-SUMMARY_DATA
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DD_PES_SUMMARY_DATA?, DPSD?
Description
Summarizes PES Analysis results. Returns average and sigma (Runout Standard Deviation) of all wedge
RROs (Repetitive Runouts), as well as the average of sigma for each wedge’s RRO.
Note: IRO = instantaneous run out, from one observation of the PES signal; RRO = repeatable run
out, the average of multiple IRO values at the same position.
Query Syntax
DD_PES_SUMMARY_DATA?
Response Format
DD_PES_SUMMARY_DATA? <avgRO>,<sigmaRO>,<avgSigma>
<avgRO> : = Average of all wedges’ RROs
<sigmaRO> : = Sigma of all wedges’ RROs in % of track separation
<avgSigma> : = Average sigma of all wedges' RROs
<avgRO> is the average distance of the head from the track, as a percentage of track separation.
<sigmaRO> Reflects the width of the distribution of all RRO values from all wedges. If the track is circular
and the head still, this should be zero.
<avgSigma> reflects the width of the distribution of IRO values that contributed to that wedge’s RRO.
This value, also given as a percentage of track separation, is increased by non-repeatable runout.
Related Commands
DD_PES_ANALYSIS, DD_PES_DATA, DD_PES_SETUP
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DD_READ_GATE_POLARITY, DRGP
Description
Selects the polarity of the read gate signal.
Command Syntax
DD_READ_GATE_POLARITY <polarity>
<polarity>:= {POS, NEG}
Query Syntax
DD_READ_GATE_POLARITY?
Response Format
DD_READ_GATE_POLARITY <polarity>
Related Commands
DD_READGATE_CHANNEL, DD_SIGNAL_INPUT
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DD_READCLOCK_CHANNEL, DRCC
Description
Specifies the input channel to which Read Clock is connected or the memory in which it is stored.
Command Syntax
DD_READCLOCK_CHANNEL <channel>
<channel>:= {NONE, C1 to Cx, M1 to Mx}
Query Syntax
DD_READCLOCK_CHANNEL?
Response Format
DD_READCLOCK_CHANNEL <channel>
Related Commands
DD_SIGNAL_INPUT
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DD_READGATE_CHANNEL, DRGC
Description
Specifies the input channel to which Read Gate is connected or the memory in which it is stored.
Command Syntax
DD_READGATE_CHANNEL <channel>
<channel>:= {NONE, C1 to Cx, M1 to Mx}
Query Syntax
DD_READGATE_CHANNEL?
Response Format
DD_READGATE_CHANNEL <channel>
Related Commands
DD_SIGNAL_INPUT, DD_READ_GATE_POLARITY
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DD_RESET_AVERAGE, DRAV
Description
Resets the averaged data and all sweeps; clears histograms and parameters; allows the start of a fresh
analysis.
Command Syntax
DD_RESET_AVERAGE
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DD_SAM_THRESH, DST
Description
Sets the SAM threshold value for channel emulation.
Command Syntax
DD_SAM_THRESH <threshold>
<threshold>:= float (range depends on signal type)
Channel emulation error threshold is in units of Sequenced Amplitude Margin (SAM). The minimum
threshold is 0.0 channel emulation without reference and –1.0 for channel emulation with reference.
Maximum allowed thresholds are:
Signal Type Maximum SAM Threshold
PR 42.00
EPR 41.00
E2PR 41.11
Query Syntax
DD_SAM_THRESH?
Response Format
DD_SAM_THRESH <threshold>
Related Commands
DD_FIND_ERROR, DD_FIND_METHOD
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DD_SAMPLE_PHASE, DSPH
Description
Adjusts the phase between the DDFA PLL sample points and an external clock reference (when RCLK is
connected).
Command Syntax
DD_SAMPLE_PHASE <phase>
<phase>:= degrees in the range -180 to +180, where the bit cell time is 360 degrees
Query Syntax
DD_SAMPLE_PHASE?
Response Format
DD_SAMPLE_PHASE <phase>
Related Commands
DD_READCLOCK_CHANNEL, DD_SIGNAL_INPUT, DD_SHOW _SAMPLE_TIMES
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DD_SHOW_FILTERED, DSF
Description
The DD_SHOW_FILTERED command enables and disables the filtering of the head signal. When enabled,
the filtered version will be displayed in the next open function Fxtrace.
Command Syntax
DD_SHOW_FILTERED <bool>
<bool>:= {OFF, ON}
Query Syntax
DD_SHOW_FILTERED?
Response Format
DD_SHOW_FILTERED <bool>
Related Commands
DD_TRAIN_FILTER
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DD_SHOW_LEVELS, DSLV
Description
Displays the level markers indicating the Viterbi levels of the ML samples when channel emulation is
active.
Command Syntax
DD_SHOW_LEVELS <bool>
<bool>:= {OFF, ON}
Query Syntax
DD_SHOW_LEVELS?
Response Format
DD_SHOW_LEVELS <bool>
Related Commands
DD_FIND_ERROR, DD_FIND_METHOD
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DD_SHOW_ML, DSML
Description
Displays/hides ML markers, cursors indicating the times and levels of the Viterbi detector ML samples,
which are available when channel emulation or NRZ compare is enabled.
Command Syntax
DD_SHOW_ML <bool>
<bool>:= {OFF, ON}
Query Syntax
DD_SHOW_ML?
Response Format
DD_SHOW_ML <bool>
Related Commands
DD_FIND_ERROR, DD_FIND_METHOD
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DD_SHOW_SAMPLE_TIMES, DSST
Description
Shows vertical-line cursors on the grid at each sample time corresponding to the read clock.
Command Syntax
DD_SHOW_SAMPLE_TIMES <bool>
<bool>:= {OFF, ON}
Query Syntax
DD_SHOW_SAMPLE_TIMES?
Response Format
DD_SHOW_SAMPLE_TIMES <bool>
Related Commands
DD_SIGNAL_INPUT, DD_READCLOCK_CHANNEL, DD_SAMPLE_PHASE
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DD_SIGNAL_INPUT, DDSI
Description
Sends or reads out the association of a source with a particular Disk Drive signal. This signal can be used
by disk drive triggers, servo analysis, analog compare, and channel emulation.
Command Syntax
DD_SIGNAL_INPUT <signal_name>,<source>[,<polarity>]
<signal_name>:= {HEAD, READ_GATE, READ_CLOCK, INDEX, SERVO_GATE,
SECTOR_PULSE, PES, ON_TRACK, WRITE_GATE}
<source>:= {None, C1 to Cx, EX, M1 to Mx}
<polarity>:= {POS, NEG}
HEAD and PES have no polarity.
EX source is not valid for HEAD, READ_GATE or READ_CLOCK signals.
M1 through Mxnot valid for SERVO_GATE, SECTOR_PULSE, PES, ON_TRACK or WRITE_GATE.
Query Syntax
DD_SIGNAL_INPUT?
Response Format
DD_SIGNAL_INPUT <signal_name>,<source>[,<polarity>]
Related Commands
DD_HEADSIGNAL_CHANNEL, DD_READGATE_CHANNEL, DD_READCLOCK_CHANNEL,
DD_READ_GATE_POLARITY
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DD_SIGNAL_TYPE, DSIG
Description
Specifies Peak Detect or a particular PRML format for the head signal.
Command Syntax
DD_SIGNAL_TYPE <sigtype>
<sigtype>:= {PEAK, PR4, EPR4, EEPR4}
Query Syntax
DD_SIGNAL_TYPE?
Response Format
DD_SIGNAL_TYPE <sigtype>
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DD_START_AVERAGING, DSAV
Description
Changes the state of the “Avg. Samples switch on the Graph menu. When set to yes, all subsequent
acquisitions will be averaged and noise analysis calculations will be carried on.
Command Syntax
DD_START_AVERAGING <bool>
<bool>:= {YES, NO}
Query Syntax
DD_START_AVERAGING?
Response Format
DD_START_AVERAGING <bool>
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DD_STORE_REFERENCE, DSTR
Description
Stores the head signal to one of the DDA’s available memories for analog compare and channel emulation
with reference.
Command Syntax
DD_STORE_REFERENCE
Related Commands
DD_FIND_ERROR, DD_OVERLAP_REF
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DD_TRAIN_FILTER?, DTF?
Description
Commands the Disk Drive Analyzer to determine reasonable values for each filter parameter. A head
signal able to be analyzed is required on which to train the filter.
Query Syntax
DD_TRAIN_FILTER?
Response Format
DD_TRAIN_FILTER <success>
<success> : = 0 or 1
Related Commands
DD_CTAF_3DB, DD_CTAF_BOOST, DD_CTAF_FC, DD_CTAF_GROUP_DELAY
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Part 6: IEEE 488.2 Command Reference
DD_VCO_SYNCH_PATTERN, DVSP
Description
Defines the number of bits per half-period in the synchronization field.
Command Syntax
DD_VCO_SYNCH_PATTERN <pattern>
<pattern>:= integer in the range 1–4 indicating type of VCO synch pattern (1T, 2T,
etc.)
Query Syntax
DD_VCO_SYNCH_PATTERN?
Response Format
DD_VCO_SYNCH_PATTERN <pattern>
Related Comamnds
DD_VCO_SYNCH_TO_DATA, DD_FIND_BITCELL
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DD_VCOSYNCH_TO_DATA, DVTD
Description
Specifies the number of bytes on the analog head signal waveform between the end of the VCO sync field
and the actual data.
Command Syntax
DD_VCOSYNCH_TO_DATA <numbytes>
<numbytes>:= integer in the range 1 to 32
Query Syntax
DD_VCOSYNCH_TO_DATA?
Response Format
DD_VCOSYNCH_TO_DATA <numbytes>
Related Commands
DD_VCO_SYNCH_PATTERN, DD_BYTE_OFFSET
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Part 6: IEEE 488.2 Command Reference
ET-PMT (Option) Commands and Queries
CUSTOM_OPTIONS?, CU_OPT?
Description
The CU_OPT? query identifies ET-PMT options currently enabled due to the presence of a PP100. These
options can also be enabled by the normal option key mechanism. If so, they are reported by the *OPT?
query instead of CU_OPT?. The response to CU_OPT? consists of a series of response fields listing all the
options enabled due to the presence of a PP100.
Query Syntax
CU_OPT?
Response Format
<option_1>, [<option_n>]
<option_n> := {MT01, MT02}
The parameter <option_n> is for compatibility with older oscilloscopes.
Related Commands
CUSTOM_APPLICATION, MT_FAIL_ACTIONS, MT_OPC?, MT_PF_COUNTERS?, MT_SELECT_TEST, MT_
SYMBOL?
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CUSTOM_APPLICATION, CUAP
Description
The CUSTOM_APPLICATION command toggles the oscilloscope application between ET-PMT Mask
Tester mode and standard oscilloscope mode.
The CUSTOM_APPLICATION query returns the current setting.
Command Syntax
CUAP <state>
<state> := [OFF, MASK_TESTER]
For compatibility with older oscilloscopes, either argument is acceptable.
Query Syntax
CUAP?
Response Format
CUAP <state>
Related Commands
CUSTOM_OPTIONS?, MT_FAIL_ACTIONS, MT_OPC?, MT_PF_COUNTERS?, MT_SELECT_TEST, MT_
SYMBOL?
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Part 6: IEEE 488.2 Command Reference
MT_FAIL_ACTION, MTFA
Description
This command sets the ET-PMT mask test actions to occur whenever a waveform does not meet the
pass criteria.
The query form of this command returns the current action settings.
Command Syntax
MTFA <action>,[...,<action>]
<action> := {STOP, STORE, DUMP, BEEP, PULSE}
Query Syntax
MTFA?
Response Format
MTFA <action>[,...,<action>]
Related Commands
CUSTOM_APPLICATION, CUSTOM_OPTIONS?, MT_OPC?, MT_PF_COUNTERS?, MT_SELECT_TEST, MT_
SYMBOL?
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MT_OFFSET, MTOF
Description
The MT_OFFSET command sets the ET-PMT mask offset value for STM-1E, STS-3E and 139M.
The MT_OFFSET query returns the offset value.
Command Syntax
MTOF <offset_value>
<offset_value>:= -50 mV to +50 mV
Query Syntax
MTOF?
Response Format
MTOF <offset_value> mV
Related Commands
CUSTOM_APPLICATION, CUSTOM_OPTIONS?, MT_OPC?, MT_PF_COUNTERS?, MT_SELECT_TEST, MT_
SYMBOL?
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Part 6: IEEE 488.2 Command Reference
MT_OPC?, MTOP?
Description
This query returns the state of the last ET-PMT operation. Its functionality is similar to the *OPC?
(operation complete) query.
Query Syntax
MTOP?
Response Format
MTOP <state>
<state> := {0, 1}
where 1 signifies "complete."
Related Commands
CUSTOM_APPLICATION, CUSTOM_OPTIONS?, MT_FAIL_ACTIONS, MT_PF_COUNTERS?, MT_SELECT_
TEST, MT_SYMBOL?
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MT_PF_COUNTERS?, MTPC?
Description
This query returns the number of passed waveforms out of the total number tested and the percent fail
rate for the last ET-PMT mask test.
Query Syntax
MTPC?
Response Format
MT_PF_COUNTERS PASS,<value>,OF,<value>,FAIL_RATE,<percent value>
Related Commands
CUSTOM_APPLICATION, CUSTOM_OPTIONS?, MT_FAIL_ACTIONS, MT_OPC?, MT_SELECT_TEST, MT_
SYMBOL?
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Part 6: IEEE 488.2 Command Reference
MT_SELECT_TEST, MTST
Description
The MT_SELECT_TEST command selects the ET-PMT signal/test type, and performs AUTOALIGN or
HORIZONTAL ALIGN actions automatically on the signal.
MT_SELECT_TEST query returns the current test settings.
Command Syntax
MTST <test_name>,<channel>,<averaging>
<test_name>:= {NO_TEST,E1TP,E1COAX,E2,E3,E4,STM1E,DS1,DS3,STS1,STS3E}
<channel>:= {C1, C2, C3, C4}
<averaging>:= {0 to 128}
Query Syntax
MTST?
Response Format
MTST <test_name>, <channel>, <averaging>
Related Commands
CUSTOM_APPLICATION, CUSTOM_OPTIONS?, MT_FAIL_ACTIONS, MT_OPC?, MT_PF_COUNTERS?, MT_
SYMBOL?
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MT_SYMBOL?, MTSY?
Description
For STM-1E, STS-3E and 139 M tests, returns the 1 or 0 symbol.
For DS1, DS3 and STS1, returns the POS or NEG pulse.
Query Syntax
MTSY?
Response Format
MTSY <bit_value>
<bit_value>:= 1 or 0, POS or NEG
Related Commands
CUSTOM_APPLICATION, CUSTOM_OPTIONS?, MT_FAIL_ACTIONS, MT_OPC?, MT_PF_COUNTERS?, MT_
SELECT_TEST
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Part 6: IEEE 488.2 Command Reference
MT_TEST_STATE, MTTS
Description
The command controls the ET-PMT test execution: RUN/STOP or PAUSE/CONTINUE.
The query returns the current ET-PMT test state.
Command Syntax
MT_TEST_STATE <test_state>
<test_state>:= {RUN, STOP, CONTINUE, PAUSE}
Query Syntax
MTTS?
Response Format
MTTS <test_state>
<test_state> := {RUN, STOP, CONTINUE, PAUSE}
Related Commands
CUSTOM_APPLICATION, CUSTOM_OPTIONS?, MT_FAIL_ACTIONS, MT_OPC?, MT_PF_COUNTERS?, MT_
SYMBOL?
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MT_VERTICAL_ALIGN, MTVA
Description
Performs offset alignment for ET-PMT masks STM-1E, STS-3E and 139M.
Command Syntax
MT_VERTICAL_ALIGN
Related Commands
CUSTOM_APPLICATION, CUSTOM_OPTIONS?, MT_FAIL_ACTIONS, MT_OPC?, MT_PF_COUNTERS?, MT_
SYMBOL?
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