Rigol DSG836A Manual de Usario
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RIGOL
Programming Guide
DSG800 Series RF Signal Generator
Sept 201. 8
RIGOL (SUZHOU) TECHNOLOGIES INC, .
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RIGOL
DSG800 Programming Guide I
Guaranty and D eclaration
Copyright
© 2015 . . RIGOL (SUZHOU) TECHNOLOGIES INC, All Rights Reserved
Trademark Information
RIGOL is a registered trademark of RIGOL .(SUZHOU) TECHNOLOGIES INC,
Publication Number
PGG02104- 1110
Software Version
00 1.0 .07
Software upgrade might change or add product features. Please acquire the latest version of the manual
from RIGOL website or contact RIGOL to upgrade the software.
Notices
RIGOL products are covered by P.R.C. and foreign patents, issued and pending.
RIGOL reserves the right to modify or change parts of or all the specifications and pricing policies at
company’s sole decision.
Information in this publication replaces all previously corresponding material.
Information in this publication is subject to change without notice.
RIGOL shall not be liable for either incidental or consequential losses in connection with the furnishing,
use, or performance of this manual, as well as any information contained.
Any part of this document is forbidden to , be copied, photocopied or rearranged without prior written
approval of . RIGOL
Product Certification
RIGOL guarantees this product conforms to the national and industrial standards in China as well as the
ISO9001:2015 standard and the ISO14001:2015 standard. Other international standard conformance
certification is in progress.
Contact Us
If you have any problem or requirement when manualusing our products or this , please contact RIGOL.
E-mail: service@rigol.com
Website: www.rigol.com
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RIGOL
II DSG800 Programming Guide
Safety Requirement
General Safety Summary
Please review the following safety precautions carefully before putting the instrument into operation so as
to avoid any personal injur or damage to the instrument and any product connected to it. To prevent y
potential hazards, please follow the instructions specified in this manual to use the instrument properly.
Use Proper Power Cord.
Only the exclusive power cord designed for the instrument and authorized for use within the local country
could be used.
Ground the Instrument.
The instrument is grounded through the Protective Earth lead of the power cord. To avoid electric shock,
connect the earth terminal of the power cord to the Protective Earth terminal before connecting any input
or output . terminals
Connect the Probe Correctly.
If a probe is used, the probe ground lead must be connected to earth ground. Do not connect the ground
lead to hig could result inh voltage. Improper way of connection dangerous voltages being present on the
connectors, controls or other surfaces of the oscilloscope and probes, which will cause potential hazards for
operators.
Observe All Terminal Ratings.
To avoid fire or shock hazard, observe all ratings and markers on the instrument and check your manual for
more information about ratings before connecting the instrument .
Use Proper Overvoltage Protection.
Ensure that no overvoltage (such as that caused by a bolt of lightning) can reach the product. Otherwise,
the operator might be exposed to the danger of an electric shock.
Do Not Operate Without Covers.
Do not operate the instrument with covers or panels removed.
Do Not Insert Objects I . nto the Air Outlet
Do not insert objects into the air outlet, as doing so may cause damage to the instrument.
Use Proper Fuse.
Please use the . specified fuses
Avoid Circuit or Wire Exposure.
Do not touch exposed junctions and components when the unit is powered . on
Do Not Operate With Suspected Failures.
If you suspect occur to the instrument, have it inspected by that any damage may RIGOL authorized
personnel before further operations. Any maintenance, adjustment or replacement especially to circuits or
accessories must be performed by RIGOL authorized personnel.
Provide Adequate Ventilation.
Inadequate ventilation may cause an increase of temperature in the instrument, which would cause
damage to the . So please keepinstrument the instrument well ventilated and inspect the air outlet and the
fan regularly.
Do Not Operate in Wet Conditions.
To avoid short circuit inside the instrument or electric shock, never operate the instrument in a humid
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RIGOL
DSG800 IIIProgramming Guide
environment.
Do Not Operate in an Explosive Atmosphere.
To avoid personal injuries or damage to the instrument, never operate the instrument in an explosive
atmosphere.
Keep Instrument . Surfaces Clean and Dry
To avoid dust or moisture from affecting the performance of the instrument, keep the surfaces of the
instrument clean and dry.
Prevent ImpactElectrostatic .
Operate the instrument in an electrostatic discharge protective environment to avoid damage induced by
static discharges. Always ground both the internal and external conductors of cables to release static before
making connections.
Use the Battery Properly.
Do not expose the ) battery (if available to high temperature or fire.
Keep it out of the reach of children. Improper change of a battery (lithium battery) may cause an explosion.
Use the RIGOL specified battery only.
Handle with Caution.
Please handle with care during transportation to avoid damage to s, knobkey s, interfaces, and other parts
on the panels.
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RIGOL
DSG800 VProgramming Guide
Allgemeine Sicherheits Informationen
Überprüfen Sie diefolgenden Sicherheitshinweise sorgfältigumPersonenschädenoderSchäden am
Gerätundan damit verbundenen weiteren Gerätenzu vermeiden. Zur Vermeidung vonGefahren, nutzen Sie
bitte das Gerät nur so, wiein diesem Handbuchangegeben.
Um Feuer oder Verletzungen zu vermeiden, verwenden Sie ein ordnungsgemäßes Netzkabel.
Verwenden Sie für dieses Gerät nur das für ihr Land zugelassene und genehmigte Netzkabel.
Erden des Gerätes.
Das Gerät ist durch den Schutzleiter im Netzkabel geerdet. Um Gefahren durch elektrischen Schlag zu
vermeiden, ist es unerlässlich, die Erdung durchzuführen. Erst dann dürfen weitere Ein- oder Ausgänge
verbunden werden.
Anschluss einesTastkopfes.
Die Erdungsklemmen der Sonden sindauf dem gleichen Spannungspegel des Instruments geerdet.
SchließenSie die Erdungsklemmen an keine hohe Spannung an.
Beachten Sie alle Anschlüsse.
Zur Vermeidung von Feuer oder Stromschlag, beachten Sie alle Bemerkungen und Markierungen auf dem
Instrument. Befolgen Sie die Bedienungsanleitung für weitere Informationen, bevor Sie weitere Anschlüsse
an das Instrument legen.
Verwenden Sie einen geeigneten Überspannungsschutz.
Stellen Sie sicher, daß keinerlei Überspannung (wie z.B. durch Gewitter verursacht) das Gerät erreichen
kann. Andernfallsbestehtfür den Anwender die GefahreinesStromschlages.
Nicht ohne Abdeckung einschalten.
Betreiben Sie das Gerät nicht mit entfernten Gehäuse- Abdeckungen.
Betreiben Sie das Gerät nicht geöffnet.
Der Betrieb mit offenen oder entfernten Gehäuseteilen ist nicht zulässig. Nichts in entsprechende
Öffnungen stecken (Lüfter z.B.)
Passende Sicherung verwenden.
Setzen Sie nur die spezifikationsgemäßen Sicherungen ein.
Vermeiden Sie ungeschützte Verbindungen.
Berühren Sie keine unisolierten Verbindungen oder Baugruppen, während das Gerät in Betrieb ist.
Betreiben Sie das Gerät nicht im Fehlerfall.
Wenn Sie am Gerät einen Defekt vermuten, sorgen Sie dafür, bevor Sie das Gerät wieder betreiben, dass
eine Untersuchung durch RIGOL autorisiertem Personal durchgeführt wird. Jedwede Wartung,
Einstellarbeiten oder Austausch von Teilen am Gerät, sowie am Zubehör dürfen nur von RIGOL
autorisiertem Personal durchgeführt werden.
Belüftung sicherstellen.
Unzureichende Belüftung kann zu Temperaturanstiegen und somit zu thermischen Schäden am Gerät
führen. Stellen Sie deswegen die Belüftung sicher und kontrollieren regelmäßig Lüfter und
Belüftungsöffnungen.
Nicht in feuchter Umgebung betreiben.
Zur Vermeidung von Kurzschluß im Geräteinneren und Stromschlag betreiben Sie das Gerät bitte niemals in
feuchter Umgebung.
Nicht in explosiver Atmosphäre betreiben.
Zur Vermeidung von Personen- und Sachschäden ist es unumgänglich, das Gerät ausschließlich fernab
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RIGOL
VI DSG800 Programming Guide
jedweder explosiven Atmosphäre zu betreiben.
Geräteoberflächen sauber und trocken halten.
Um den Einfluß von Staub und Feuchtigkeit aus der Luft auszuschließen, halten Sie bitte die
Geräteoberflächen sauber und trocken.
Schutz gegen elektrostatische Entladung (ESD).
Sorgen Sie für eine elektrostatisch geschützte Umgebung, um somit Schäden und Funktionsstörungen
durch ESD zu vermeiden. Erden Sie vor dem Anschluß immer Innen- und Außenleiter der
Verbindungsleitung, um statische Aufladung zu entladen.
Die richtige Verwendung desAkku.
Wenneine Batterieverwendet wird, vermeiden Sie hohe Temperaturen bzw. Feuer ausgesetzt werden.
Bewahren Sie es außerhalbder Reichweitevon Kindern auf. UnsachgemäßeÄnderung derBatterie
(Anmerkung: Lithium - Batterie) kann zu einer Explosion führen. VerwendenSie nur von RIGOL
angegebenenAkkus.
Sicherer Transport.
Transportieren Sie das Gerät sorgfältig (Verpackung!), um Schäden an Bedienelementen, Anschlüssen und
anderen Teilen zu vermeiden.
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RIGOL
DSG800 VIIProgramming Guide
Sicherheits Begriffe und Symbole
Begriffe in diesem Guide:
WARNING
Die Kennzeichnung WARNING beschreibt Gefahrenquellen die leibliche Schäden oder den
Tod von Personen zur Folge haben können.
CAUTION
Die Kennzeichnung Caution (Vorsicht) beschreibt Gefahrenquellen die Schäden am Gerät
hervorrufen können.
Begriffe auf dem Produkt:
DANGER
weist auf eine Verletzung oder Gefährdung hin, die sofort geschehen kann.
WARNING
weist auf eine Verletzung oder Gefährdung hin, die möglicherweise nicht sofort
geschehen.
CAUTION
weist auf eine Verletzung oder Gef bedeutet, dass eine mögliche ä hrdung hin und
Beschädigung des Instruments oder anderer Gegenstände auftreten kann.
Symbole auf dem Produkt:
Gefährliche
Spannung
Sicherheits-
Hinweis Schutz- erde Gehäusemasse Erde
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RIGOL
VIII DSG800 Programming Guide
Document Overview
This manual introduces how to the RF signal generator over program the remote interfaces in details.
Main Topics in this Manual:
Chapter 1 Programming Overview
This chapter outlines how to build the remote communication between the RF signal generator and PC and
how to RF signal control the generator remotely. Besides, brief it also provides a introduction of the SCPI
commands.
Chapter 2 Command System
This chapter introduces the syntax, function, parameter and using instruction of each DSG800 command in
alphabetical order (from A to Z).
Chapter 3 Application Examples
This chapter provides the application examples of the main functions of the RF signal generator. In the
application examples, a series of commands are combined to realize the basic functions of the RF signal
generator.
Chapter 4 Programming Demos
This chapter using introduces how to program and control DSG800 development tools, such as Visual C++,
Visual Basic and LabVIEW.
Chapter 5 Appendix
This chapter provides various information, such as ry setting list. facto
Tip
The latest version of this manual can be downloaded from www.rigol.com.
Format Conventions in this Manual:
1. Key
The key at the front panel is denoted by the format of "Key Name (Bold) + Text Box" in the manual. For
example, FREQ denotes the FREQ key.
2. Menu
The menu item is denoted by the format of " " Menu Word (Bold) + Character Shading in the manual.
For example, LF denotes the "LF" menu item under FREQ.
3. Operation Step
The next step of operation is denoted by an arrow "" in the manual. For example, FREQ LF
denotes pressing FREQ at . the front panel and then pressing LF
Content Conventions in this Manual:
DSG800 series RF signal generator includes DSG830 and DSG815. The introductions of the DSG800 series
commands in this manual are based on DSG830, unless otherwise noted.
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Contents RIGOL
DSG800 IXProgramming Guide
Contents
Guaranty and Declaration ......................................................................................................... I
Safety Requirement .................................................................................................................. II
General Safety Summary ............................................................................................................. II
Safety Notices and Symbols ......................................................................................................... IV
Allgemeine Sicherheits Informationen ........................................................................................... V
Sicherheits Begriffe und Symbole ............................................................................................... VII
Document Overview ............................................................................................................. VIII
Chapter 1 Programming Overview...................................................................................... 1-1
To Build Remote Communication ............................................................................................... 1-2
Remote Control Methods ........................................................................................................... 1-3
SCPI Command Overview .......................................................................................................... 1-4
Syntax ............................................................................................................................... 1-4
Symbol Description ............................................................................................................ 1-4
Parameter Type .................................................................................................................. 1-5
Command Abbreviation ...................................................................................................... 1-5
Chapter 2 Command System ............................................................................................... 2-1
IEEE488.2 Common Commands ................................................................................................. 2-2
*IDN? ............................................................................................................................... 2-2
*TRG ................................................................................................................................ 2-2
:MMEMory Commands .............................................................................................................. 2-3
:MMEMory:CATalog ............................................................................................................ 2-3
:MMEMory:CATalog:LENGth ................................................................................................ 2-4
:MMEMory:COPY ................................................................................................................ 2-4
:MMEMory:DATA:IQ ........................................................................................................... 2-5
:MMEMory:DATA:IQ:LIST ................................................................................................... 2-5
:MMEMory:DELete .............................................................................................................. 2-6
:MMEMory:DISK:FORMat .................................................................................................... 2-6
:MMEMory:DISK:INFormation ............................................................................................. 2-6
:MMEMory:FILEtype ........................................................................................................... 2-7
:MMEMory:LDISk:SPACe ..................................................................................................... 2-7
:MMEMory:LOAD ................................................................................................................ 2-7
:MMEMory:MDIRectory ....................................................................................................... 2-8
:MMEMory:MOVE ............................................................................................................... 2-8
:MMEMory:PNAMe:EDIT ..................................................................................................... 2-9
:MMEMory:PNAMe:STATe .................................................................................................... 2-9
:MMEMory:SAVe ............................................................................................................... 2-10
:OUTPut Command ................................................................................................................. 2-11
:OUTPut[:STATe] .............................................................................................................. 2-11
:SOURce Commands ............................................................................................................... 2-12
[:SOURce]:AM Command Subsystem................................................................................. 2-12
[:SOURce]:CORRection Command Subsystem .................................................................... 2-18
[:SOURce]:FM Command Subsystem ................................................................................. 2-20
[:SOURce]:FMPM:TYPE..................................................................................................... 2-25
[:SOURce]:FREQuency Command Subsystem .................................................................... 2-26
[:SOURce]:INPut:TRIGger:SLOPe ...................................................................................... 2-27
[:SOURce]:IQ Command Subsystem ................................................................................. 2-28
[:SOURce]:LEVel Command Subsystem ............................................................................. 2-41
[:SOURce]:LFOutput Command Subsystem........................................................................ 2-43
[:SOURce]:MODulation:STATe ........................................................................................... 2-45
[:SOURce]:PM Command Subsystem ................................................................................. 2-46
[:SOURce]:PULM Command Subsystem ............................................................................. 2-51
[:SOURce]:SWEep Command Subsystem ........................................................................... 2-61
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RIGOL Contents
X DSG800 Programming Guide
:STATus Commands ................................................................................................................. 2-78
:STATus:OPERation:CONDition........................................................................................... 2-81
:STATus:OPERation:ENABle ............................................................................................... 2-81
:STATus:OPERation[:EVENt] .............................................................................................. 2-81
:STATus:QUEStionable:CALibration:CONDition .................................................................... 2-82
:STATus:QUEStionable:CALibration:ENABle ......................................................................... 2-83
:STATus:QUEStionable:CALibration[:EVENt] ........................................................................ 2-83
:STATus:QUEStionable:CONDition ...................................................................................... 2-83
:STATus:QUEStionable:CONNect:CONDition ........................................................................ 2-84
:STATus:QUEStionable:CONNect:ENABle ............................................................................ 2-85
:STATus:QUEStionable:CONNect[:EVENt] ........................................................................... 2-85
:STATus:QUEStionable:ENABle........................................................................................... 2-85
:STATus:QUEStionable[:EVENt].......................................................................................... 2-86
:STATus:QUEStionable:FREQuency:CONDition .................................................................... 2-87
:STATus:QUEStionable:FREQuency:ENABle ......................................................................... 2-88
:STATus:QUEStionable:FREQuency[:EVENt] ........................................................................ 2-88
:STATus:QUEStionable:MODulation:CONDition .................................................................... 2-89
:STATus:QUEStionable:MODulation:ENABle ........................................................................ 2-90
:STATus:QUEStionable:MODulation[:EVENt] ....................................................................... 2-90
:STATus:QUEStionable:POWer:CONDition ........................................................................... 2-91
:STATus:QUEStionable:POWer:ENABle ............................................................................... 2-92
:STATus:QUEStionable:POWer[:EVENt] .............................................................................. 2-92
:STATus:QUEStionable:SELFtest:CONDition ........................................................................ 2-93
:STATus:QUEStionable:SELFtest:ENABle ............................................................................. 2-94
:STATus:QUEStionable:SELFtest[:EVENt] ............................................................................ 2-94
:STATus:QUEStionable:TEMP:CONDition ............................................................................. 2-95
:STATus:QUEStionable:TEMP:ENABle ................................................................................. 2-96
:STATus:QUEStionable:TEMP[:EVENt] ................................................................................ 2-96
:SYSTem Commands ............................................................................................................... 2-97
:SYSTem:BRIGhtness ........................................................................................................ 2-98
:SYSTem:CLEar ................................................................................................................ 2-98
:SYSTem:COMMunication:INTerface ................................................................................... 2-98
:SYSTem:COMMunication:LAN:DHCP .................................................................................. 2-99
:SYSTem:COMMunication:LAN:IP:ADDress ......................................................................... 2-99
:SYSTem:COMMunication:LAN:IP:AUTO ........................................................................... 2-100
:SYSTem:COMMunication:LAN:IP:GATeway ...................................................................... 2-100
:SYSTem:COMMunication:LAN:IP:MANual ........................................................................ 2-101
:SYSTem:COMMunication:LAN:IP:SET .............................................................................. 2-101
:SYSTem:COMMunication:LAN:IP:SUBnet:MASK ............................................................... 2-102
:SYSTem:COMMunication:LAN:RESet ............................................................................... 2-102
:SYSTem:COMMunication:LAN[:SELF]:PREFerred .............................................................. 2-102
:SYSTem:DATE ............................................................................................................... 2-103
:SYSTem:DISPlay:UPDate[:STATe] ................................................................................... 2-103
:SYSTem:FSWitch:STATe ................................................................................................. 2-104
:SYSTem:LANGuage ........................................................................................................ 2-104
:SYSTem:LKEY ............................................................................................................... 2-105
:SYSTem:POWer:ON:TYPE .............................................................................................. 2-105
:SYSTem:PRESet ............................................................................................................ 2-106
:SYSTem:PRESet:TYPE .................................................................................................... 2-106
:SYSTem:PRESet:SAVE .................................................................................................... 2-106
:SYSTem:TIME ............................................................................................................... 2-107
:SYSTem:TIME:STATe ..................................................................................................... 2-107
:TRIGger Commands ............................................................................................................. 2-108
:TRIGger:IQ[:IMMediate] ................................................................................................ 2-108
:TRIGger:PULSe[:IMMediate] .......................................................................................... 2-108
:TRIGger[:SWEep][:IMMediate] ...................................................................................... 2-108
:UNIT Command ................................................................................................................... 2-109
:UNIT:POWer ................................................................................................................. 2-109
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Contents RIGOL
DSG800 Programming Guide XI
Chapter 3 Application Examples ......................................................................................... 3-1
To Output RF signal .................................................................................................................. 3-2
To Output RF Sweep Signal ....................................................................................................... 3-2
To Output RF Modulated Signal.................................................................................................. 3-3
Chapter 4 Programming Demos .......................................................................................... 4-1
Programming Preparations ........................................................................................................ 4-2
Excel Programming Demo ......................................................................................................... 4-3
Matlab Programming Demo ....................................................................................................... 4-7
LabVIEW Programming Demo.................................................................................................... 4-8
Visual Basic Programming Demo .............................................................................................. 4-12
Visual C++ Programming Demo .............................................................................................. 4-15
Chapter 5 Appendix ............................................................................................................ 5-1
Appendix A: Factory Setting ...................................................................................................... 5-1
Appendix B: Warranty ............................................................................................................... 5-4
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Chapter 1 Programming Overview RIGOL
DSG800 1-1 Programming Guide
Chapter 1 Programming Overview
This chapter s howintroduce build to the remote communication between the instrument and PC and
provides an overview of the syntax, abbreviation rules and status system of the SCPI commands.
Main topics of this chapter:
To Build Remote Communication
Remote Control Methods
SCPI Command Overview
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RIGOL Chapter 1 Programming Overview
1-2 DSG800 Programming Guide
To Build Remote Communication
You can build the remote communication between DSG800 and the PC via USB or LAN interface.
Operating Steps:
1. Install the Ultra Sigma common PC software
Acquire the ; then, install it according to the Ultra Sigma scommon PC oftware from www.rigol.com
instructions.
2. Connect the instrument and PC and configure the interface parameters of the instrument
DSG800 supports USB and LAN communication interfaces, as shown in the figure below.
LAN EVICEUSB D
Figure DSG1-1 8 00 Communication Interfaces
(1) Use the USB interface:
Connect the USB DEVICE interface at the rear interface of the panel of DSG800 and the USB HOST
PC using a USB cable.
(2) Use the LAN interface:
Make sure that your PC is connected to the local network.
Check whether your local network supports P DHCP or auto I mode. If not, you need to
acquire the network interface parameters available, including the IP address, subnet mask,
gateway and DNS.
Connect DSG800 to the local network using a network cable.
Press Syst I/O Config IP LAN to configure the address, subnet mask, gateway and
DNS of the instrument.
3. Check whether the connection is successful
Start up - Ultra Sigma, search for the RF signal generator resource, right-click the resource name and
select "SCPI Panel Control" from the pop- - up menu. Enter the correct command in the pop up SCPI
control panel and click Send Command, Read Response or Send&Read to check whether the
connection is successful, as shown in the figure on the next page (take the USB interface as an
example).
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RIGOL Chapter 1 Programming Overview
1-4 DSG800 Programming Guide
SCPI Command Overview
SCPI (Standard Commands for Programmable Instruments) is a standardized instrument programming
language that is based on the standard IEEE488.1 and IEEE488.2 and conforms to various standards (such
as the floating point operation rule in stanIEEE754 dard, ISO646 7-bit coded character for information
interchange (equivalent to ASCll ) s s programming) . This chapter describes the syntax, symbol , parameter
and abbreviation rules of the SCPI commands.
Syntax
SCPI subcommands present ical a hierarch tree structure and have multiple -systems, each of which
contains a root keyword and one or more sub- " "keywords. The command string usually begins with :; the
keywords are separted by " " :and are followed by the parameter settings available; " " ?is added at the end
of the command string to indicate query; space is used to separate the command and parameter.
For example,
:SYSTem:COMMunica :LAN:IPtion : Dr > AD ess <value
:SYSTem:COMMunicat :LAN:IPion : Dress? AD
SYSTem IP Dress is the root keyword of the command above. COMMunication, , LAN and AD are the
second- - - -level, third level, forth level and fifth level keywords respectively. The command string begins with
":" -level < > which is also used to separate the multi keywords. value denotes the parameter available for
setting. "?" denotes query the RF signal generator returns the response information (the output value and
or internal setting value of the instrument) when receiving a query command. The
command :SYSTem:COMMunication:LAN:IP: Dress AD and prarameter < > value are separated by a space.
"," is generally used for separating different parameters contained in the same command for example, ;
[:SOURce] LIST:LIST?: :SWEep < Start>,<Count>
Symbol Description
The following four symbols are not the content of SCPI commands and will not be sent with the command;
but, they are usually used to describe the parameters in the commands.
1. Braces { }
M ultiple optional parameters are enclosed in the braces and one of the parameters must be selected
when sending the command.
2. Vertical B |ar
The vartical bar is used to separate multiple parameters. When you send a command, one of the
parameters must be selected. For example, the :SYSTem:LANGuage CHINese|ENGLish command.
3. S Brackets ]quare [
The contents (command keywords) enclosed in the square brackets are optional and will be executed
no matter whether they are omitted or not For example,. :for the [:SOURce]:AM[ DEPTh]? command,
s ending any of the four commands below can generate the same effect.
: ? AM
: : ? AM DEPTh
:SOURce:AM?
:SOURce:AM: ? DEPTh
4. Triangle Brackets ><
The parameter enclosed in the triangle brackets must be replaced by an effective value. For example,
send the command in [:SOURce]:FREQuency <value> :FREQuency 4MHz form.
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Chapter 1 Programming Overview RIGOL
DSG800 1-5Programming Guide
Parameter Type
The parameters of the commands introduced in this manual contains 5 types: bool, integer, real number,
discrete and ASCII string.
1. Bool
The parameter could be OFF ON [:SOU, , 0 or 1. For example, Rce]:AM:STATe ON|OFF|1|0.
2. Integer
Unless otherwise noted, the parameter can be any integer within the effective value range. Note that
do not set the parameter to a decimal; otherwise, errors will occur. For example, in
the :SYSTem:BRIGhtness and, <value> comm <value> can be any integer from 1 to 8.
3. Real Number
Unless otherwise noted, the parameter can be any within the effective value range. value
For example, command can be any real number <value> in the [:SOURce]:AM:FREQuency <value>
from 10Hz to 100kHz.
4. Discrete
The parameter could only be one of specified values or characters. For example, inthe the
[:SOURce]:AM:WAVEform SINE|SQUA command, the parameter can only be SINE SQUA or .
5. ASCII String
The parameter should be the combinations of ASCII characters. For example, in the :MMEMory:SAVe
<file_name> command, <file_name> is the filename of the file to be saved and can include Chinese
characters (a Chinese character occupies two bytes), English characters and numbers. The filename
cannot . exceed 28 bytes
Command Abbreviation
All the commands are case insensitive and you can use any of them. If abbreviation is used, all the capital -
letters in the command must be written completely. For example, the :MMEMory:DISK:FORMat command
can be abbreviated to :MMEM:DISK:FORM.
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Chapter 2 Command System RIGOL
DSG800 2-1 Programming Guide
Chapter 2 Command System
This chapter introduces the syntax, function, parameter and using instruction of each DSG800 command in
alphabetical (A to Z) order.
Main topics of this chapter:
IEEE488.2 Common Commands
:MMEMory Commands
:OUTPut Command
:SOURce Commands
:STATus Commands
:SYSTem Commands
:TRIGger Commands
:UNIT Command
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RIGOL Chapter 2 Command System
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IEEE488.2 Common Commands
The IEEE488.2 common commands are used to query the basic information about the instrument or
execute common operations. These commands usually begin with "* -", contain a 3 character command
keyword and relate to the status register.
Command List[1] :
*IDN?
*TRG
*IDN?
Syntax *IDN?
Description
Query the ID string of the instrument.
Return Format The query returns the ID string of the instrument. For example, R igol
Technologies,D A1 1 SG830,DSG8 70200001,00.0 .01.
*TRG
Syntax *TRG
Description Trigger a pulse modulation, RF sweep or IQ wavetable output immediately.
Related
Commands
:TRIGger:IQ[:IMMediate]
:TRIGger:PULSe[:IMMediate]
:TRIGger[:SWEep][:IMMediate]
Note[1]: In the " " Command List in this manual, the parameters in the setting commands and the query commands are
not included and you can refer to the complete introductions of the commands in the text according to the keywords.
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Chapter 2 Command System RIGOL
DSG800 2-3Programming Guide
:MMEMory Commands
The :MM EMory commands are used to store files to the internal or external memory of the instrument, read
or delete the specified file as well as query the disk information.
Command List:
:MMEMory:CATalog
:MMEMory:CATalog:LENGth
:MMEMory:COPY
:MMEMory:DATA:IQ
:MMEMory:DATA:IQ:LIST
:MMEMory:DELete
:MMEMory:DISK:FORMat
:MMEMory:DISK:INFormation
:MMEMory:FILEtype
:MMEMory:LDISk:SPACe
:MMEMory:LOAD
:MMEMory:MDIRectory
:MMEMory:MOVE
:MMEMory:PNAMe:EDIT
:MMEMory:PNAMe:STATe
:MMEMory:SAVe
:MMEMory:CATalog
Syntax :MMEMory:CATalog? <path>
Description Query all the files and folders under the specified path.
Parameter Name Type Range Default
<path> ASCII string Valid path --
Explanation <path>: the local memory (D disk), external memory (E disk; when a USB
storage device is detected by the USB HOST interface at the rear panel) or the
subdirectory under the D or E disk.
The query returns a list of all the files and folders under the path specified by
<path>.
Return Format NO.1 File Name: Rigol
NO.2 File Name: 4.STA
Example
:MMEM:CAT? D:
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RIGOL Chapter 2 Command System
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:MMEMory:CATalog:LENGth
Syntax :MMEMory:CATalog:LENGth? <path>
Description Query the number of files and folders under the specified path.
Parameter
Name
Type
Range
Default
<path>
ASCII string
Valid path
--
Explanation <path> can be the local memory (D disk), external memory (E disk; when a USB
storage device is detected by the USB HOST interface at the rear panel) or the
subdirectory under the D or E disk.
Return Format The query returns an integer. For example, 2.
Example :MMEM:CAT:LENG? D: /*Query and return the number of files and folders in the
D disk*/
:MMEMory:COPY
Syntax
:MMEMory:COPY <file_source>,<file_destination>
Description Copy the file or folder specified by <file_ source> to the destination path specified
by <file_destination>.
Parameter Name Type Range Default
<file_source> ASCII string The name of the file or folder to
be copied
--
<file_destination> Valid ASCII string destination path --
Explanation <file_ Tsource> denotes the file or folder to be copied. he file or folder name
must contain the path. denotes the destination path and <file_destination>
does not include the filename.
If the file or folder specified by <file_source> does not exist, the operation
fails.
If the destination path specified by <file_destination> does not exist, the copy
operation fails.
Example
:MMEM:COPY \ , \ D: 1.STA D:
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Chapter 2 Command System RIGOL
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:MMEMory:DATA:IQ
Syntax :MMEMory:DATA:IQ <file_name>,<flag>,<num>{,<i0>,<q0>…<in>,<qn>}
Description Save and download IQ waveform data to the instrument.
Parameter
Name
Type
Explanation
<file_name> ASCII string The name of the wavetable file downloaded
into the instrument.
<flag> Discrete
When the IQ data file exceeds 64kB, you
should download the file packets separately.
0 denotes downloading the first data packet;
1 denotes downloading the subsequent data
packets;
2 denotes downloading the last data packet
and output the IQ waveform.
<num>
Integer
The number of IQ data pairs.
{,<i0>,<q0>
…
<in>,<qn>}
Decimal
number
IQ data pairs. Each data (for example, i0)
cannot exceed two bytes.
Explanation When sending the command, you should add the data block (start with #9 flag)
which denotes the total length of the IQ data before <i0>,<q0> <in>,<qn>… . For
example, #9000000011 denotes that the total length of the IQ data is 11 bytes. The
value is calculated by the formula "the number of bytes of the IQ + tdata pairs he
number of bytes occupied by the commas".
Example :MMEM:DATA:IQ test1,0,2,#9000000011 1,10,11,20
/*Save the two pairs of IQ data currently edited with the filename "test1" (the total
length of "1,10,11,20" is 11 bytes and is #9000000011) and download expressed by
the IQ data to DSG800*/
:MMEMory:DATA:IQ:LIST
Syntax :MMEMory:DATA:IQ:LIST?
Description Query the wavetable files currently stored in the root directory (D: disk) of the
instrument.
Return Format The query returns the wavetable file list in the format of "wavetable filename
(*.arb),file size". For example, ,. wave2.arb, ,wa2180 ve3.arb,2516
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:MMEMory:DELete
Syntax
:MMEMory:DELete <file_name>
Description
Delete the specified file or folder under the specified operation path.
Parameter
Name
Type
Range
Default
<file_name> ASCII string The name of the file or folder to
be deleted
--
Explanation This command is valid only when the specified file or folder exists under the
current operation path or the specified path.
<file_name> can be the name of a file or folder under the current operation
path or a file or folder name containing the specified path. For
example, :MMEM:DEL D:\ \8.NEW STA.
Example :MMEM:DEL 8.STA /*Delete the file named " " 8.STA under the current operation
path*/
:MMEMory:DISK:FORMat
Syntax :MMEMory:DISK:FORMat
Description Format the local disk (D disk).
:MMEMory:DISK:INFormation
Syntax
:MMEMory:DISK:INFormation? <Disk>
Description Query the information of the local disk.
Parameter
Name
Type
Range
Default
<Disk>
ASCII string
D: (or LOCAL)
D: (or LOCAL)
Return Format The query returns the information of the local disk, including the disk name, file
system, total space, used space and free space. For example,
Disk:D: Disk:LOCAL) (or
File Sys:FAT32
Total:1.0 GB
Used:512 KB
Free:0.99 GB
Example
:MMEM:DISK:INF? D: /*The query returns the information of D disk*/
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Chapter 2 Command System RIGOL
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:MMEMory:FILEtype
Syntax :MMEMory:FILEtype
ALL|STATe|ARB|FLACsv|SWPCsv|TRNCsv|SEGMent|SEQList|SEQCsv
:MMEMory:FILEtype?
Description Set the file type.
Query the current file type.
Parameter
Name
Type
Range
Default
ALL|STATe|ARB|FLACsv|S
WPCsv|TRNCsv|SEGMent|
SEQList|SEQCsv Discrete
ALL|STATe|ARB|FLACsv|S
WPCsv|TRNCsv|SEGMent|
SEQList|SEQCsv ALL
Explanation The file types available are all, sta Arb, flatness csv, sweep csv, train csv, te,
segment, seg list and seg csv.
After selecting the corresponding file type, you can view all the files of this file
type or save a new file of this file type.
Return Format The query returns ALL, , STATE
ARB, FLACSV, SWPCSV, TRNCSV, SEGMENT, SEQLIS
or SEQCSV.
Example :MMEM:FILE STATe /*Set the file type to "State"*/
:MMEM:FILE? /*Query the current file type and the query returns
STATE*/
:MMEMory:LDISk:SPACe
Syntax :MMEMory:LDISk:SPACe?
Description Query the space information of the local disk (D disk).
Return Format The query returns the D disk space information including the "Used space" and "Free
space". For example, Used:512 k,Free:1048064 k.
:MMEMory:LOAD
Syntax
:MMEMory:LOAD <f ile_name>
Description
Read the specified file in the specified operation path.
Parameter
Name
Type
Range
Default
<file_name> ASCII
string
The name of the file to be
read
--
Explanation This command is valid only when the specified file exists under the current
operation path or the specified path.
<file_name> can be a file the name of a file under the current operation path or
name containing the specified path. F \ \ .or example, MMEM:LOAD D: NEW 2.STA
Example :MMEM:LOAD 2.STA /*Read the file named " " 2.STA under the current operation
path*/
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:MMEMory:MDIRectory
Syntax
:MMEMory:MDIRectory <directory_name>
Description Create a new folder under the specified operation path.
Parameter
Name
Type
Range
Default
<directory_name> ASCII string The name of the folder to be
created
--
Explanation The folder name can include Chinese characters (a Chinese character occupies
two bytes), . English characters or numbers The folder name cannot exceed 28
bytes.
If the name of the folder to be created already exists, this operation is invalid. At
this point, "The filename already exists" is displayed in the user interface.
<directory_name> can be a new folder name that does not contain the path
(denote creating a folder under the current operation path) or a folder name
t hat contains the specified path (denote creating a new folder under the
specified path; for example, :MMEM:MDIR D:\1\NEW).
Example :MMEM:MDIR a NEW /*Create folder named "NEW" under the current operation
path*/
:MMEMory:MOVE
Syntax
:MMEMory:MOVE <file_source>,<file_destination>
Description Rename the file or folder specified by as the destination file or folder <file_source>
name specified by <file_destination>.
Parameter
Name
Type
Range
Default
<file_source>
<file_destination> ASCII string Valid file or folder name --
Explanation The file or folder s <file_destination> name specified by <file_source> and
must contain the path.
If the file or folder specified by <file_source> does not exist, the rename
operation fails.
If the destination file or folder name specified by <file_destination> already
exists under the current path, the rename operation fails.
Example
:MMEM:MOVE D:\ , 1.STA D:\2. STA
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Chapter 2 Command System RIGOL
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:MMEMory:PNAMe:EDIT
Syntax :MMEMory:PNAMe:EDIT <pre_name>
:MMEMory:PNAMe:EDIT?
Description Edit and save the filename prefix.
Query the filename prefix saved.
Parameter
Name
Type
Range
Default
<pre_name>
ASCII string
The filename prefix to be edited
--
Explanation You can edit any filename prefix.
Return Format The query returns the filename prefix. For example, N.
Example :MMEM:PNAM:EDIT Edit N /* the filename prefix as N*/
:MMEM:PNAM:EDIT? /*The query returns N*/
Related
Command
:MMEMory:PNAMe:STATe
:MMEMory:PNAMe:STATe
Syntax :MMEMory:PNAMe:STATe ON|OFF|1|0
:MMEMory:PNAMe:STATe?
Description Turn on or off the filename prefix.
Query the current on/off state of the filename prefix.
Parameter
Name
Type
Range
Default
ON|OFF|1|0 ON|OFF|1|0 Bool OFF|0
Explanation ON|1: turn on the filename prefix edited.
OFF|0: turn off the filename prefix edited.
If the filename prefix is turned on, the prefix edited will be added to the
filename input box automatically when saving a file.
Return Format The query returns 0 or 1.
Example :MMEM:PNAM:STATe ON
:MMEM:PNAM:STAT?
Related
Command
:MMEMory:PNAMe:EDIT
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:MMEMory:SAVe
Syntax
:MMEMory:SAVe <File_name>
Description
Save the file with the specified filename under the current operation path.
Parameter
Name
Type
Range
Default
<file_name>
ASCII string
The name of the file to be saved
--
Explanation T ile he f name can include Chinese characters (a Chinese character occupies two
bytes), English characters or numbers. The filename cannot exceed 28 bytes.
When the current path already contains a file with the same name, this
command will directly overwrite the original file.
Example :MMEM:SAV SET.STA /*Save the current instrument state with the filename
"SET.STA" under the current operation path*/
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Chapter 2 Command System RIGOL
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:OUTPut Command
Command List:
:OUTPut
:OUTPut[:STATe]
Syntax :OUTPut[:STATe] ON|OFF|1|0
:OUTPut[:STATe]?
Description Turn on or off the RF output.
Query the on/off state of the RF output.
Parameter Name Type Range Default
ON|OFF ON|OFF|1|0 Bool |1|0 O FF|0
Explanation ON|1: turn on the RF output. At this point, the backlight of RF/on .goes on
OFF|0: turn off the RF output. At this point, the backlight of RF/on goes off.
Return Format
The query returns 1 or 0.
Example :OUTP ON /*Turn on the RF output*/
:OUTP? /*The query returns 1*/
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:SOURce Commands
The :SOURce commands are used to set the related parameters of the main functions of the RF signal
generator including the frequency, level, flatness calibration, AM, FM/ M, Pulse, SWEEP, LF output and so Ø
on.
Command List:
[:SOURce]:AM system Command Sub
[:SOURce]:CORRection Command Subsystem
[:SOURce]:FM Command Subsystem
[:SOURce]:FMPM:TYPE
[:SOURce]:FREQuency Command Subsystem
[:SOURce]:INPut:TRIGger:SLOPe
[:SOURce]:IQ Command Subsystem
[:SOURce]:LEVel Command Subsystem
[:SOURce]:LFOutput Command Subsystem
[:SOURce]:MODulation:STATe
[:SOURce]:PM Command Subsystem
[:SOURce]:PULM Command Subsystem
[:SOURce]:SWEep Command Subsystem
[:SOURce]:AM Command Subsystem
Command List:
[:SOURce]:AM[ ] :DEPTh
[:SOURce]:AM[ ]:DEPTh :STEP[:INCRement]
[:SOURce]:AM:EXT:COUP
[:SOURce]:AM:EXT:IMP
[:SOURce]:AM:FREQuency
[:SOURce]:AM:FREQuency:STEP[:INCRement]
[:SOURce]:AM:SOURce
[:SOURce]:AM:STATe
[:SOURce]:AM:WAVEform
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[:SOURce]:AM[ ] :DEPTh
Syntax [:SOURce]:AM[ ] :DEPTh <value>
[:SOURce]:AM[ ]? :DEPTh
Description Set the modulation depth.AM
Query the . AM modulation depth
Parameter
Name
Type
Range
Default
<value>
Real
0 to 100
50
Explanation When "Int" modulation source is selected, the AM modulation depth (
a
m
) and
amplitude (difference
sb
ΔP
) between the carrier and sideband satisfy the s
following relation:
asb mΔP lg206 −=
.
<value> can also be expressed as percentage. For example, 80%.
After the modulation depth is set, you can rotate knob to modify the the
modulation depth at the current step. You can set and query the current step
using the [ ][:SOURce]:AM :DEPTh :STEP[:INCRement] command.
Return Format The query returns the modulation depth. For example, 80.00.
Example :AM:DEPT 80
:AM:DEPT?
Related
Command
[:SOURce]:AM :STEP[:INCRement][ ]:DEPTh
[:SOURce]:AM :STEP[:INCRement][ ]:DEPTh
Syntax [:SOURce]:AM[ ]:DEPTh :STEP[:INCRement] <value>
[:SOURce]:AM :STEP[:INCRement]?[ ]:DEPTh
Description Set the modulation depth AM step.
Query the AM modulation depth step.
Parameter
Name
Type
Range
Default
<value>
Real
0.1 to 50
10
Explanation <value> can also be expressed as percentage. For example, 0.2%.
After the modulation depth step is set, you can rotate the knob to modify the
modulation depth at the current step. At this point, you can query or set the
modulation depth .using the [ ][:SOURce]:AM :DEPTh command
Return Format The query returns the modulation depth step. For example, 0.20.
Example AM:DEPT:STEP:INCR 0.2
AM:DEPT:STEP:INCR?
Related
Command
[:SOURce]:AM[ ] :DEPTh
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[:SOURce]:AM:EXT:COUP
Syntax [:SOURce]:AM:EXT:COUP | AC DC
[:SOURce]:AM:EXT:COUP?
Description Set the coupling mode of AM external modulation.
Query the coupling mode of AM external modulation.
Parameter
Name
Type
Range
Default
AC| DC
Discrete
AC| DC
AC
Explanation AC: set the coupling mode of AM external modulation to "AC".
DC: set the coupling mode of AM external modulation to "DC".
When the modulation source of AM is set to "Int", this command is invalid.
Return Format
The query returns AC or DC.
Example :AM:EXT:COUP AC
:AM:EXT:COUP?
Related
Command
[:SOURce]:AM:SOURce
[:SOURce]:AM:EXT:IMP
Syntax [:SOURce]:AM:EXT:IMP | 50 600|100k
[:SOURce]:AM:EXT:IMP?
Description Set the impedance of AM external modulation.
Query the impedance of AM external modulation.
Parameter Name Type Range Default
50 600|100k 50 600|100k 100k| Discrete |
Explanation 50: set the impedance of AM external modulation to "50ohm".
600: set the impedance of AM external modulation to "600ohm".
100k: set the impedance of AM external modulation to "100kohm".
When the modulation source of AM is set to "Int", this command is invalid.
Return Format The query returns 50, 600 or 100k.
Example :AM:EXT:IMP 600
:AM:EXT:IMP?
Related
Command
[:SOURce]:AM:SOURce
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[:SOURce]:AM:FREQuency
Syntax [:SOURce]:AM:FREQuency <value>
[:SOURce]:AM:FREQuency?
Description Set the AM modulation frequency.
Query the odulation requency AM m f .
Parameter
Name
Type
Range
Default
<value> Real 10Hz to 100kHz (Sine)/10Hz to 20kHz
(Square)
10kHz
Explanation When <value> is set in "Number" form, the default unit is Hz; for example,
20000. In addition, can also be set in "Number + Unit" form; for <value>
example, 20kHz.
After the modulation frequency is set, you can rotate the knob to modify the
modulation frequency at the current step. You can set and query the current
step using the [:SOURce]:AM:FREQuency:STEP[:INCRement] command.
When the modulation source of AM is set to "Ext", this command is invalid.
Return Format The query returns the AM modulation frequency. For example, 20.00000kHz.
Example :AM:FREQ 20kHz
:AM:FREQ?
Related
Commands
[:SOURce]:AM:FREQuency:STEP[:INCRement]
[:SOURce]:AM:SOURce
[:SOURce]:AM:FREQuency:STEP[:INCRement]
Syntax [:SOURce]:AM:FREQuency:STEP[:INCRement] <value>
[:SOURce]:AM:FREQuency:STEP[:INCRement]?
Description Set the AM m f odulation requency step.
Query the odulation requency AM m f step.
Parameter
Name
Type
Range
Default
<value> Real 1Hz to 50kHz 1kHz
Explanation When <value> is set in "Number" form, the default unit is Hz. In addition,
<value> can also be set in "Number + Unit" form; for example, 3.55kHz.
After the modulation frequency step is set, you can rotate the knob to modify
the modulation frequency at the current step. At this point, you can query or set
the modulation frequency using the [:SOURce]:AM:FREQuency command.
Return Format The query returns the AM modulation frequency step. For example, 3.55000kHz.
Example :AM:FREQ:STEP 3.55kHz
:AM:FREQ:STEP?
Related
Command
[:SOURce]:AM:FREQuency
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[:SOURce]:AM:SOURce
Syntax [:SOURce]:AM:SOURce EXTernal|INTernal
[:SOURce]:AM:SOURce?
Description Set the AM modulation source.
Query ourcethe odulation AM m s .
Parameter
Name
Type
Range
Default
EXTernal|INTernal EXTernal|INTernal Discrete INTernal
Explanation EXTernal: set the modulation source to "Ext". At this point, the external
modulating signal is input from the [ ] EXT MOD IN connector.
INTernal: set the modulation source to "Int". At this point, the instrument
provides the modulating signal and you can set the modulation frequency and
modulation waveform of the modulating signal.
Return Format The query returns the AM modulation source. For example, EXT.
Example :AM:SOUR EXT
:AM:SOUR?
Related
Commands
[:SOURce]:AM:FREQuency
[:SOURce]:AM:WAVEform
[:SOURce]:AM:STATe
Syntax [:SOURce]:AM:STATe ON|OFF|1|0
[:SOURce]:AM:STATe?
Description Set the state of the AM switch.
Query the state of the AM switch.
Parameter Name Type Range Default
ON|OFF|1|0 ON|OFF|1|0 Bool OFF|0
Explanation ON|1: turn on the AM switch to enable the AM function.
OFF|0: turn off the AM switch to disable the AM function.
Return Format The query returns 1 0. or
Example :AM:STAT ON /*Turn on the AM switch*/
:AM:STAT? /*The query returns 1*/
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[:SOURce]:AM:WAVEform
Syntax [:SOURce]:AM:WAVEform SINE|SQUA
[:SOURce]:AM:WAVEform?
Description Set the AM modulation waveform.
Query the AM modulation waveform.
Parameter
Name
Type
Range
Default
SINE|SQUA SINE|SQUA SINE Discrete
Explanation SINE: set the AM modulation waveform to "Sine".
SQUA: set the AM modulation waveform to "Square".
When the modulation source of AM is set to "Ext", this command is invalid.
Return Format The query returns SINE SQUA or .
Example :AM:WAVE SQUA
:AM:WAVE?
Related
Command
[:SOURce]:AM:SOURce
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[:SOURce]:CORRection Command Subsystem
Command List:
[:SOURce]:CORRection:FLATness:COUNt
[:SOURce]:CORRection:FLATness:LIST
[:SOURce]:CORRection:FLATness[:STATe]
[:SOURce]:CORRection:FLATness:COUNt
Syntax [:SOURce]:CORRection:FLATness:COUNt?
Description Query the number of points in the current flatness calibration list.
Return Format The query returns the number of points in the flatness calibration list in integer. For
example, 5.
[:SOURce]:CORRection:FLATness:LIST
Syntax
[:SOURce]:CORRection:FLATness:LIST? <Start>,<Count>
Description Q uery the flatness calibration list data within the specified range.
Parameter
Name
Type
Range
Default
<Start> list Integer 1 to the total number of rows in the current --
<Count>
Integer
1 to the total number of rows in the current list
--
Explanation <Start>: the number of the start row of the data to be acquired.
<Count>: the total number of rows of the data to be acquired.
Return Format The query returns the flatness calibration list data acquired. For example,
NO.1:304000000.000000 , 7.450000
NO.2:800000000.000000 , -17.799999
Example :CORR:FLAT:LIST? Query 2,2 /* and return two rows of calibration data starting
from the 2nd row of the flatness calibration list*/
Related
Command
[:SOURce]:CORRection:FLATness:COUNt
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg27.png)
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[:SOURce]:CORRection:FLATness[:STATe]
Syntax [:SOURce]:CORRection:FLATness[:STATe] ON|OFF|1|0
[:SOURce]:CORRection:FLATness[:STATe]?
Description Turn on or off the flatness calibration switch.
Query the state of the flatness calibration switch.
Parameter
Name
Type
Range
Default
ON|OFF|1|0
Bool
ON|OFF|1|0
OFF|0
Explanation ON|1: turn on the flatness calibration switch.
OFF|0: turn off the flatness calibration switch.
Return Format The query returns 1 or 0.
Example :CORR:FLAT ON /*Turn on the flatness calibration switch*/
:CORR:FLAT? /*The query returns 1*/
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg28.png)
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[:SOURce]:FM Command Subsystem
Command List:
[:SOURce]:FM[:DEViation]
[:SOURce]:FM[:DEViation]:STEP[:INCRement]
[:SOURce]:FM:EXT:COUP
[:SOURce]:FM:EXT:IMP
[:SOURce]:FM:FREQuency
[:SOURce]:FM:FREQuency:STEP[:INCRement]
[:SOURce]:FM:SOURce
[:SOURce]:FM:STATe
[:SOURce]:FM:WAVEform
[:SOURce]:FM[ ] :DEViation
Syntax [:SOURce]:FM[:DEViation] <value>
[:SOURce]:FM[:DEViation]?
Description S . et the FM frequency deviation
Query the FM frequency deviation.
Parameter
Name
Type
Range
Default
<value> R eal 100mHz to
1MHz
10kHz
Explanation When alue><v is set in "Number" form, the default unit is Hz; for example,
20000. In addition, can also be set in "Number + Unit" form; for <value>
example, 20kHz.
After the frequency deviation is set, you can rotate the knob to modify the
deviation at the current step. You can set and query the current step using the
[:SOURce]: :STEP[:INCRement]FM[:DEViation] command.
Return Format
The query returns the FM frequency deviation. For example, 20.00000kHz.
Example :FM:DEV 0kHz 2
:FM:DEV?
Related
Command
[:SOURce]: :STEP[:INCRement]FM[:DEViation]
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg29.png)
Chapter 2 Command System RIGOL
DSG800 21 2-Programming Guide
[:SOURce]: :STEP[:INCRement]FM[ ]:DEViation
Syntax [:SOURce]:FM[:DEViation]:STEP[:INCRement] <value>
[:SOURce]:FM[:DEViation]:STEP[:INCRement]?
Description Set the FM frequency deviation step.
Query the FM frequency deviation step.
Parameter
Name
Type
Range
Default
<value>
Real
10mHz to 500kHz
1kHz
Explanation When <value> is set in "Number" form, the default unit is Hz; for example,
5000. In addition, <value> can also be set in "Number + Unit" form; for
example, 5kHz.
After the frequency deviation step is set, you can rotate the knob to modify the
deviation at the current step. At this point, You can query or set the current
frequency deviation using the [:DEViation] [:SOURce]:FM command.
Return Format The query returns the FM frequency deviation step. For example, 5.00000kHz.
Example :FM:STEP:INCR 5kHz
:FM:STEP:INCR?
Related
Command
[:SOURce]:FM[:DEViation]
[:SOURce]:F M:EXT:COUP
Syntax [:SOURce]:FM:EXT:COUP | AC DC
[:SOURce]:FM:EXT:COUP?
Description Set the coupling mode of FM external modulation.
Query the coupling mode of FM external modulation.
Parameter
Name
Type
Range
Default
AC AC AC| Discrete DC | DC
Explanation AC: set the coupling mode of FM external modulation to "AC".
DC: set the coupling mode of FM external modulation to "DC".
When the modulation source of FM is set to "Int", this command is invalid.
Return Format The query returns AC or DC.
Example :F M:EXT:COUP AC
:FM:EXT:COUP?
Related
Command
[:SOURce]:FM:SOURce
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg2a.png)
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[:SOURce]:F M:EXT:IMP
Syntax [:SOURce]:FM:EXT:IMP | 50 600|100k
[:SOURce]:FM:EXT:IMP?
Description Set the impedance of FM external modulation.
Query the impedance of FM external modulation.
Parameter
Name
Type
Range
Default
50 600|100k|
Discrete
50 600|100k|
100k
Explanation 50: set the impedance of FM external modulation to "50ohm".
600: set the impedance of FM external modulation to "600ohm".
100k: set the impedance of FM external modulation to "100kohm".
When the modulation source of FM is set to "Int", this command is invalid.
Return Format
The query returns 50, 600 or 100k.
Example :FM:EXT:IMP 600
:FM:EXT:IMP?
Related
Command
[:SOURce]:FM:SOURce
[:SOURce]:FM:FREQuency
Syntax [:SOURce]:FM:FREQuency <value>
[:SOURce]:FM:FREQuency?
Description Set the FM modulation frequency.
Query the odulation requency FM m f .
Parameter
Name
Type
Range
Default
<value> Real 10Hz to 100kHz (Sine)/10Hz to 20kHz
(Square)
10kHz
Explanation When <value> is set in "Number" form, the default unit is Hz; for example,
20000. In addi can also be set in "Number + Unit" form; for tion, <value>
example, 20kHz.
After the modulation frequency is set, you can rotate the knob to modify the
modulation frequency at the current step. ou can set and queryAt this point, y
the current step using the [:SOURce]:FM:FREQuency:STEP[:INCRement]
command.
When the modulation source of FM is set to "Ext", this command is invalid.
Return Format
The query returns the FM modulation frequency. For example, 20.00000kHz.
Example :FM:FREQ 20kHz
:FM:FREQ?
Related
Commands
[:SOURce]:FM:FREQuency:STEP[:INCRement]
[:SOURce]:FM:SOURce
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[:SOURce]:FM:FREQuency:STEP[:INCRement]
Syntax [:SOURce]:FM:FREQuency:STEP[:INCRement] <value>
[:SOURce]:FM:FREQuency:STEP[:INCRement]?
Description Set the F mM odulation requencyf step.
Query the odulation requency FM m f step.
Parameter
Name
Type
Range
Default
<value> Real 1Hz to 50kHz 1kHz
Explanation When <value> is set in "Number" form, the default unit is Hz; for example,
5 000. In addition, <value> can also be set in "Number + Unit" form; for
example, 5kHz.
After the modulation frequency step is set, you can rotate the knob to modify
the modulation frequency at the current step. At this point, you can query or set
the modulation frequency using the [:SOURce]:FM:FREQuency command.
Return Format The query returns the FM modulation frequency step. For example, 5.00000kHz.
Example :FM:FREQ:STEP 5kHz
:FM:FREQ:STEP?
Related
Command
[:SOURce]:FM:FREQuency
[:SOURce]:FM:SOURce
Syntax [:SOURce]:FM:SOURce EXTernal|INTernal
[:SOURce]:FM:SOURce?
Description Set the FM modulation source.
Query ourcethe odulation FM m s .
Parameter
Name
Type
Range
Default
EXTernal|INTernal
Discrete
EXTernal|INTernal
INTernal
Explanation EXTernal: set the modulation source to "Ext". At this point, the external
modulating signal is input from the [ ] EXT MOD IN connector.
INTernal: set the modulation source to "Int". At this point, the instrument
provides the modulating signal and you can set the modulation frequency and
modulation waveform of the modulating signal.
Return Format
The query returns the FM modulation source. For example, INT.
Example :FM:SOUR INT
:FM:SOUR?
Related
Commands
[:SOURce]:FM:FREQuency
[:SOURce]:FM:WAVEform
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[:SOURce]:FM:STATe
Syntax [:SOURce]:FM:STATe ON|OFF|1|0
[:SOURce]:FM:STATe?
Description Set the state of the FM switch.
Query the state of the FM switch.
Parameter
Name
Type
Range
Default
ON|OFF|1|0
Bool
ON|OFF|1|0
OFF|0
Explanation ON|1: turn on the FM switch to enable the FM function.
OFF|0: turn off the FM switch to disable the FM function.
Return Format The query returns 1 or 0.
Example :FM:STAT ON /*Turn on the FM switch*/
:FM:STAT 1*/? /*The query returns
[:SOURce]:FM:WAVEform
Syntax [:SOURce]:FM:WAVEform SINE|SQUA
[:SOURce]:FM:WAVEform?
Description Set the FM modulation waveform.
Query the FM modulation waveform.
Parameter
Name
Type
Range
Default
SINE|SQUA SINE|SQUA SINE Discrete
Explanation SINE: set the FM modulation waveform to "Sine".
SQUA: set the FM modulation waveform to "Square".
When the modulation source of FM is set to "Ext", this command is invalid.
Return Format The query returns SINE SQUA or .
Example :F M:WAVE SQUA
:F ? M:WAVE
Related
Command
[:SOURce]:FM:SOURce
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[:SOURce]:FMPM:TYPE
Syntax [:SOURce]:FMPM:TYPE FM|PM
[:SOURce]:FMPM:TYPE?
Description Set the current modulation type to FM or ØM.
Query the current modulation type.
Parameter
Name
Type
Range
Default
FM|PM FM|PM PM Discrete
Explanation FM: set the current modulation type to "FM".
PM ØM: set the current modulation type to " ".
Return Format
The query returns FM . or PM
Example :FMPM:TYPE FM
:FMPM:TYPE?
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg2e.png)
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[:SOURce]:FREQuency Command Subsystem
Command List:
[:SOURce]:FREQuency
[:SOURce]:FREQuency:STEP
[:SOURce]:FREQuency
Syntax [:SOURce]:FREQuency <value>
[:SOURce]:FREQuency?
Description Set the frequency of the RF signal.
Query the frequency of the RF signal.
Parameter
Name
Type
Range
Default
<value> Real 9kHz to 3GHz 3GHz
Explanation When <value> is set in "Number" form, the default unit is Hz; for example,
4000000. In addition, can also be set in "Number + Unit" form; for <value>
example, 4MHz.
After the RF frequency is set, you can rotate the knob to modify the frequency
at the current step. At this point, you can set and query the current step using
the [:SOURce]:FREQuency:STEP command.
Return Format The query returns the frequency of the RF signal. For example, 4.00000000MHz.
Example :FREQ 4MHz
:FREQ?
Related
Command
[:SOURce]:FREQuency:STEP
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg2f.png)
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[:SOURce]:FREQuency:STEP
Syntax [:SOURce]:FREQuency:STEP <value>
[:SOURce]:FREQuency:STEP?
Description Set the RF frequency step.
Query the RF frequency step.
Parameter Name Type Range Default
<value>
Real
10mHz to 1GHz
100MHz
Explanation When <value> is set in "Number" form, the default unit is Hz; for example,
3000. In addition, <value> can also be set in "Number + Unit" form; for
example, 3kHz.
After the RF frequency step is set, you can rotate the knob to modify the
frequency at the current step. At this point, you can query or set the frequency
using the [:SOURce]:FREQuency command.
Return Format
The query returns the RF frequency step. For example, 3.00000kHz.
Example :FREQ:STEP 3kHz
:FREQ:STEP?
Related
Command
[:SOURce]:FREQuency
[:SOURce]:INPut:TRIGger:SLOPe
Syntax [:SOURce]:INPut:TRIGger:SLOPe POSitive|NEGative
[:SOURce]:INPut:TRIGger:SLOPe?
Description Set the polarity of the external trigger input signal.
Query the polarity of the external trigger input signal.
Parameter Name Type Range Default
POSitive|NEGative POSitive|NEGative POSitive Discrete
Explanation This command is valid only when the trigger mode of SWEEP is set to "Ext".
The external trigger signal is input from the [TRIGGER IN] connector at the
rear panel.
Return Format The query returns POS or NEG.
Example :INP:TRIG:SLOP POS
:INP:TRIG:SLOP?
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg30.png)
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[:SOURce]:IQ Command Subsystem
Command List [2] :
[:SOURce]:IQ:BASeout:LEVel
[:SOURce]:IQ:BASeout:LEVel:STEP
[:SOURce]:IQ:BASeout:STATe
[:SOURce]:IQ:MODe
[:SOURce]:IQ:MODe:STATe
[:SOURce]:IQ:SAMPle
[:SOURce]:IQ:SAMPle:STEP
[:SOURce]:IQ:TRIGger:ARB
[ :SOURce]:IQ:TRIGger:DELay
[:SOURce]:IQ:TRIGger:DELay:STEP
[:SOURce]:IQ:TRIGger:DURation
[:SOURce]:IQ:TRIGger:DURation:STEP
[:SOURce]:IQ:TRIGger:DURation:UNIT
[:SOURce]:IQ:TRIGger:INHibit
[:SOURce]:IQ:TRIGger:INHibit:STEP
[:SOURce]:IQ:TRIGger:MODe
[:SOURce]:IQ:TRIGger:OPTMode
[:SOURce]:IQ:TRIGger:SEGMent:CURRent?
[:SOURce]:IQ:TRIGger:SEGMent:EXECute
[:SOURce]:IQ:TRIGger:SEGMent:MODE
[:SOURce]:IQ :TRIGger:SEGMent:NEXT
Note [2] : If you want to use related commands, please order RF signal generator IQ-the s -IQ with the DSG800 option.
Otherwise, the command settings . are invalid
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg31.png)
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[:SOURce]:IQ:BASeout:LEVel
Syntax [:SOURce]:IQ:BASeout:LEVel <value>
[:SOURce]:IQ:BASeout:LEVel?
Description Set t output amplitudehe baseband .
Query the baseband output amplitude.
Parameter
Name
Type
Range
Default
<value> Real 20mV to 1.5V 1V
Explanation When <value> is set in "Number" form, the default unit is V. Besides, <value>
can also be set in "Number + Unit" form; for example, 1.1V.
The default unit of the return value is V.
After the baseband output amplitude is set, you can rotate the knob to modify
the amplitude at the current step. At this point, you can set and query the
current step using the [:SOURce]:IQ:BASeout:LEVel:STEP command.
Return Format The query returns the amplitude of the baseband output signal. For example,
1.100000.
Example :IQ:BAS:LEV 1.1
:IQ:BAS:LEV?
Related
Command
[:SOURce]:IQ:BASeout:LEVel:STEP
[:SOURce]:IQ:BASeout:LEVel:STEP
Syntax [:SOURce]:IQ:BASeout:LEVel:STEP <value>
[:SOURce]:IQ:BASeout:LEVel:STEP?
Description Set the baseband output amplitude step.
Query the baseband output amplitude step.
Parameter Name Type Range Default
<value>
Real
0.01V to 0.5V
0.1V
Explanation When <value> is set in "Number" form, the default unit is V. Besides, <value>
can also be set in "Number + Unit" form; for example, 0.2V.
The default unit of the return value is V.
After the baseband output amplitude step is set, you can rotate the knob to
modify the baseband output amplitude at the current step. At this point, you can
query or set the baseband output amplitude using the
[:SOURce]:IQ:BASeout:LEVel command.
Return Format The query returns the baseband output amplitude step. For example, 0.200000.
Example :IQ:BAS:LEV:STEP 0.2
:IQ:BAS:LEV:STEP?
Related
Command
[:SOURce]:IQ:BASeout:LEVel
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[:SOURce]:IQ:BASeout:STATe
Syntax [:SOURce]:IQ:BASeout:STATe ON|OFF|1|0
[:SOURce]:IQ:BASeout:STATe?
Description Set the state of the baseband output switch.
Query the state of the baseband output switch.
Parameter
Name
Type
Range
Default
ON|OFF|1|0 ON|OFF|1|0 Bool OFF|0
Explanation ON|1: turn on the baseband output switch.
OFF|0: turn off the baseband output switch.
Return Format The query returns 1 or 0.
Example :IQ:BAS:STAT ON /*Turn on the baseband output switch*/
:IQ:BAS:STAT? /*The query returns 1*/
[:SOURce]:IQ:MODe
Syntax [:SOURce]:IQ:MODe INTernal|EXTernal
[:SOURce]:IQ:MODe?
Description Set the IQ modulation source.
Query the IQ modulation source.
Parameter
Name
Type
Range
Default
INTernal|EXTernal INTernal|EXTernal Discrete INTernal
Explanation INTernal: select "Int" modulation source. At this point, the modulating signal is
provided by the built-in baseband generator (wavetable) of the instrument. In
addition, if the IQ switch is turned modulation on, the baseband output switch
will be turned on automatically. The RF signal generator can output the I
(In-Phase) components and Q (Quadrature Phase) components of the IQ
modulation baseband signal from the [I OUT] and [Q OUT] connectors at the
rear panel respectively.
EXTernal: select "Ext" modulation source. At this point, the In-Phase and
Quadrature Phase baseband signals of IQ modulation are input from the [I IN]
and [Q IN] connectors at the rear panel respectively. In addition, when the
baseband output switch is turned on, the Quadrature PhaseIn-Phase and
components of the I/Q modulation baseband signal generated by the built-in
baseband generator (wavetable) can be output from the [I OUT] and [Q OUT]
connectors at the rear panel respectively.
Return Format The query returns the IQ modulation source. For example, INT.
Example : INT IQ:MOD
: IQ:MOD?
Related
Command
[:SOURce]:IQ:BASeout:STATe
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Chapter 2 Command System RIGOL
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[:SOURce]:IQ:MODe:STATe
Syntax [:SOURce]:IQ:MODe:STATe ON|OFF|1|0
[:SOURce]:IQ:MODe:STATe?
Description Set the state of the IQ modulation switch.
Query the state of the IQ modulation switch.
Parameter
Name
Type
Range
Default
ON|OFF|1|0
Bool
ON|OFF|1|0
OFF|0
Explanation ON|1: enable the IQ modulation function.
OFF|0: disable the IQ modulation function.
Return Format
The query returns 1 or 0.
Example :IQ:MOD /*E */:STAT ON nable the IQ modulation function
: IQ:MOD */:STAT? /*The query returns 1
[:SOURce]:IQ:SAMPle
Syntax [:SOURce]:IQ:SAMPle <value>
[:SOURce]:IQ:SAMPle?
Description Set the sample rate of the IQ wavetable output.
Query the sample rate of the IQ wavetable output.
Parameter
Name
Type
Range
Default
<value>
Real
1kHz to 100MHz
1MHz
Explanation When <value> is set in "Number" form, the default unit is Hz; for example,
3 000. In addition, <value> can also be set in "Number + Unit" form; for
example, 3kHz.
The default unit of the return value is Hz.
After the is set, you can rotate the knob to modify the sample rate sample rate
at the current step. At this point, you can set and query the current step using
the [:SOURce]:IQ:SAMPle:STEP command.
Return Format The query returns the sample rate of the IQ wavetable output. For example, 3000.
Example :IQ:SAMP 3kHz
:IQ:SAMP?
Related
Command
[:SOURce]:IQ:SAMPle:STEP
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[:SOURce]:IQ:SAMPle:STEP
Syntax [:SOURce]:IQ:SAMPle:STEP <value>
[:SOURce]:IQ:SAMPle:STEP?
Description Set the sample rate step of the IQ wavetable output.
Query the sample step rate of the IQ wavetable output.
Parameter Name Type Range Default
<value> Real 1Hz to 10MHz 1MHz
Explanation When <value> is set in "Number" form, the default unit is Hz; for example,
3000. In addition, < value> can also be set in "Number + Unit" form; for
example, 3kHz.
The default unit of the return value is Hz.
After the sample rate step of IQ wavetable output rotate theis set, you can
knob to modify the sample rate at the current step. At this point, you can query
or set the sample rate using the [:SOURce]:IQ:SAMPle command.
Return Format The query returns the sample step rate of the IQ wavetable output. For example,
3000.
Example :IQ:SAMP:STEP 3kHz
:IQ:SAMP:STEP?
Related
Command
[:SOURce]:IQ:SAMPle
[:SOURce]:IQ:TRIGger:ARB
Syntax [:SOURce]:IQ:TRIGger:ARB
Description Stop the waveform output manually.
Explanation When the operation mode after the IQ wavetable is triggered is set to "Arm Auto" or
"Arm Retrig", you need to use this command to stop the waveform output manually
and wait for the next trigger.
Related
Command
[:SOURce]:IQ:TRIGger:OPTMode
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[ :SOURce]:IQ:TRIGger:DELay
Syntax [:SOURce]:IQ:TRIGger:DELay <value>
[:SOURce]:IQ:TRIGger:DELay?
Description Set the external trigger delay of the IQ modulation baseband signal.
Query the external trigger delay of the IQ . modulation baseband signal
Para meter
Name
Type
Range
Default
<value> 0 Integer 0 to 65535
Explanation The external delay refers to the delay of the response to a trigger when the
external trigger signal is received.
This command is valid only when "Ext" trigger mode is selected. Wherein,
<value> (describes the number of points d
N
). The actual (time
d
T
) can be
obtained according to the current sample rate (
a
S
):
add SN T =
.
After the trigger delay is set, you can rotate the knob to modify the delay at the
current step. At this point, you can set and query the current step using the
[:SOURce]:IQ:TRIGger:DELay:STEP command.
Return Format The query returns the external trigger delay. For example, 300.
Example :IQ:TRIG:DEL 300
:IQ:TRIG:DEL?
Related
Commands
[:SOURce]:IQ:TRIGger:DELay:STEP
[:SOURce]:IQ:TRIGger:MODe
[:SOURce]:IQ:TRIGger:DELay:STEP
Syntax [:SOURce]:IQ:TRIGger:DELay:STEP <value>
[:SOURce]:IQ:TRIGger:DELay:STEP?
Description Set the external trigger delay step of the IQ modulation baseband signal.
Query the external trigger delay step of the IQ modulation baseband signal.
Parameter
Name
Type
Range
Default
<value>
Integer
1 to 10000
1
Explanation After the trigger delay step is set, you can rotate the knob to modify the trigger delay
at the current step. At this point, you can query or set the using thetrigger delay
[ :SOURce]:IQ:TRIGger:DELay command.
Return Format The query returns the external trigger delay step. For example, 20.
Example :IQ:TRIG:DEL:STEP 20
:IQ:TRIG:DEL:STEP?
Related
Command
[ :SOURce]:IQ:TRIGger:DELay
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[:SOURce]:IQ:TRIGger:DURation
Syntax [:SOURce]:IQ:TRIGger:DURation <value>
[:SOURce]:IQ:TRIGger:DURation?
Description Set the duration of the signal in single trigger.
Query the duration of the signal in single trigger.
Parameter
Name
Type
Range
Default
<value>
Integer
1 to 65535
1
Explanation This command is valid only when "Single" operation mode is selected. Wherein,
<value> (describes the number of points
r
N
). The actual (time
r
T
) can be
obtained according to the current sample rate (
a
S
):
arr SN T =
.
After the duration is set, you can rotate the knob to modify the at the duration
current step. At this point, you can set and query the current step using the
[:SOURce]:IQ:TRIGger:DURation:STEP command.
Return Format The query returns the duration of a single signal output. For example, 4000.
Example :IQ:TRIG:DUR 4000
:IQ:TRIG:DUR?
Related
Commands
[:SOURce]:IQ:TRIGger:DURation:STEP
[:SOURce]:IQ:TRIGger:OPTMode
[:SOURce]:IQ:TRIGger:DURation:STEP
Syntax [:SOURce]:IQ:TRIGger:DURation:STEP <value>
[:SOURce]:IQ:TRIGger:DURation:STEP?
Description Set the duration step.
Query the duration step.
Parameter Name Type Range Default
<value>
Integer
1 to 10000
1
Explanation After the at the duration step , you can rotate the knob to modify the is set duration
current step. At this point, you can query or set the using theduration
[:SOURce]:IQ:TRIGger:DURation command.
Return Format The query returns the duration step. F or example, 500.
Example :IQ:TRIG:DUR:STEP 500
:IQ :TRIG:DUR:STEP?
Related
Command
[:SOURce]:IQ:TRIGger:DURation
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg37.png)
Chapter 2 Command System RIGOL
DSG800 35 2-Programming Guide
[:SOURce]:IQ:TRIGger:DURation:UNIT
Syntax [:SOURce]:IQ:TRIGger:DURation:UNIT SEQUENCE|SAMPLES
[:SOURce]:IQ:TRIGger:DURation:UNIT?
Description Set the duration unit of the IQ wavetable in "Single" trigger.
Query the duration unit of the IQ wavetable in "Single" trigger.
Parameter Name Type Range Default
SEQUENCE|SAMPLES SEQUENCE|SAMPLES SAMPLES Discrete
Explanation SEQUENCE: trigger by the waveform segment.
SAMPLES: trigger by the data point.
Return Format The query returns the duration unit of the IQ wavetable in "Single" trigger. For
example, SAMPLES.
Example :IQ:TRIG:DUR:UNIT SAMPLES
:IQ:TRIG:DUR:UNIT?
Related
Command
[:SOURce]:IQ:TRIGger:OPTMode
[:SOURce]:IQ:TRIGger:INHibit
Syntax [:SOURce]:IQ:TRIGger:INHibit <value>
[:SOURce]:IQ:TRIGger:INHibit?
Description Set the trigger inhibit of the IQ modulation baseband signal.
Query the trigg er inhibit of the IQ modulation baseband signal.
Parameter
Name
Type
Range
Default
<value>
Integer
0 to 65535
0
Explanation Trigger inhibit refers to the time from when a trigger signal is received to when
the instrument receives the next trigger signal.
This command is valid only when "Ext" trigger mode is selected. <value>
describes the number of points (
i
N
). The actual (time
i
T
) can be obtained
according to the current sample rate (
a
S
):
aii
SN T =
.
After the is set, you can rotatetrigger inhibit the knob to modify the inhibit at
the current step. At this point, you can set and query the current step using the
[:SOURce]:IQ:TRIGger:INHibit:STEP command.
Return Format
The query returns the trigger inhibit. For example, 5000.
Example :IQ:TRIG:INH 5000
:IQ:TRIG:INH?
Related
Commands
[:SOURce]:IQ:TRIGger:INHibit:STEP
[:SOURce]:IQ:TRIGger:MODe
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg38.png)
RIGOL Chapter 2 Command System
2- 36 DSG800 Programming Guide
[:SOURce]:IQ:TRIGger:INHibit:STEP
Syntax [:SOURce]:IQ:TRIGger:INHibit:STEP <value>
[:SOURce]:IQ:TRIGger:INHibit:STEP?
Description Set the trigger inhibit step.
Query the inhibittrigger step.
Parameter Name Type Range Default
<value>
Integer
1 to 10000
1
Explanation After the step is set, you can rotate the knob to modify the trigger inhibit trigger
inhibit at the current step. At this point, you can query or set the trigger inhibit using
the Q:TRIGger:INHibit [:SOURce]:I command.
Return Format The query returns the trigger inhibit step. For example, 555.
Example :IQ:TRIG:INH:STEP 555
:IQ:TRIG:INH:STEP?
Related
Command
[:SOURce]:IQ:TRIGger:INHibit
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg39.png)
Chapter 2 Command System RIGOL
DSG800 37 2-Programming Guide
[:SOURce]:IQ:TRIGger:MODe
Syntax [:SOURce]:IQ:TRIGger:MODe AUTO|KEY|BUS|EXT
[:SOURce]:IQ:TRIGger:MODe?
Description Set the trigger mode of the IQ modulation baseband output.
Query the trigger mode of the IQ modulation baseband output.
Parameter
Name
Type
Range
Default
AUTO|KEY|BUS|EXT
Discrete
AUTO|KEY|BUS|EXT
AUTO
Explanation AUTO: select "Auto" trigger mode. At this point, the RF signal generator fulfills
the trigger condition at any time and will output the IQ baseband signal
continuously.
KEY: select "Key" trigger mode. At this point, the instrument will output the
baseband signal each time Key Trig is pressed.
BUS: select "Bus" trigger mode. At this point, the instrument will output the
baseband signal each time the *TRG :TRIGger: or IQ[:IMMediate] command is
sent.
EXT: select "Ext" trigger mode. At this point, the RF signal generator receives
the external trigger signal input from the [TRIGGER IN] connector at the rear
panel. The instrument will output the baseband signal each time a TTL pulse
with the specified polarity is received.
When "Ext" trigger mode is selected, you can also set the "Ext Delay" and "Ext
Inhibit".
Return Format The query returns the trigger mode of the IQ modulation baseband output. For
example, KEY.
Example :IQ:TRIG:MOD KEY
:IQ:TRIG:MOD?
Related
Commands
[ :SOURce]:IQ:TRIGger:DELay
[:SOURce]:IQ:TRIGger:INHibit
*TRG
:TRIGger:IQ[:IMMediate]
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg3a.png)
RIGOL Chapter 2 Command System
2- 38 DSG800 Programming Guide
[:SOURce]:IQ:TRIGger:OPTMode
Syntax [:SOURce]:IQ: RETRig|AMDAuto|AMDRetrig|SINGleTRIGger:OPTMode
[:SOURce]:IQ:TRIGger:OPTMode?
Description Set the operation mode after the IQ modulation baseband signal is triggered.
Query the operation mode after the IQ modulation baseband signal is triggered.
Parameter
Name
Type
Range
Default
RETRig|AMDAuto|
AMDRetrig|SINGle
Discrete
RETRig|AMDAuto|
AMDRetrig|SINGle
RETRig
Explanation RETRig: select the "Retrig" mode. At this point, the instrument outputs the
baseband s ignal continuously and restarts to output the signal each time a
trigger is received.
AMDAuto: select the "Arm Auto" mode. The instrument starts outputting the
waveform is continuously each time a trigger is received until "Arm ARB"
selected and then waits for the next trigger.
AMDRetrig: select the "Arm Retrig" mode. The instrument starts outputting the
waveform s continuously each time a trigger is received; the instrument restart
outputting the signal when another trigger is received until "Arm ARB" is
selected and then waits for the next trigger.
SINGle : select the "Single" mode. The instrument outputs the specified length
(specified in "Duration") of waveform each time a trigger is received and then
stops to wait for the next trigger.
Return Format The query returns the operation mode after the IQ modulation baseband signal is
triggered. For example, RETRIG.
Example :IQ:TRIG:OPTM RETR
:IQ:TRIG:OPTM?
Related
Commands
[:SOURce]:IQ:TRIGger:ARB
[:SOURce]:IQ:TRIGger:DURation
[:SOURce]:IQ:TRIGger:SEGMent:CURRent?
Syntax [:SOURce]:IQ:TRIGger:SEGMent:CURRent?
Description Query the number of the current wavetable segment.
Return Format The query returns the number of the current wavetable segment. For example, 1.
[:SOURce]:IQ:TRIGger:SEGMent:EXECute
Syntax [:SOURce]:IQ:TRIGger:SEGMent:EXECute
Description Execute the trigger of the next segment.
Explanation This command is only valid when a "Segment" file is loaded and the segment trigger
mode is set to "Next Seg" or "Seamless".
Related
Command
[:SOURce]:IQ:TRIGger:SEGMent:MODE
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg3b.png)
Chapter 2 Command System RIGOL
DSG800 39 2-Programming Guide
[:SOURce]:IQ:TRIGger:SEGMent:MODE
Syntax [:SOURce]:IQ:TRIGger:SEGMent:MODE SAME|NEXT|SEAMLESS|SEQUENCER
[:SOURce]:IQ:TRIGger:SEGMent:MODE?
Description Set the trigger mode of the IQ data segment.
Query the trigger mode of the IQ data segment.
Parameter
Name
Type
Range
Default
SAME|NEXT|SEAMLESS
|SEQUENCER
Discrete SAME|NEXT|SEAMLESS
|SEQUENCER
SAME
Explanation SAME: select the "Same Seg" mode. At this point, the RF signal generator
outputs the same trigger segment.
NEXT: select the "Next Seg" mode. At this point, the instrument will switch to
the output of the next segment when the
[:SOURce]:IQ:TRIGger:SEGMent:EXECute command is sent.
SEAMLESS: select the "Seamless" mode. At this point, the instrument will switch
to the output of the next segment seamlessly when the
[:SOURce]:IQ:TRIGger:SEGMent:EXECute command is sent. This parameter is
valid only when the sample rates of all the waveform segments in the
"Segment" file loaded are the same.
SEQUENCER: select the "Sequencer" mode. At this point, the instrument
outputs each waveform segment according to the "Seg List" (*.SEQ) file or "Seg
csv" (*.CSV) file loaded. At this point, the
[:SOURce]:IQ:TRIGger:SEGMent:NEXT and
[:SOURce]:IQ:TRIGger:SEGMent:EXECute commands are invalid. In addition,
this parameter is valid only when the "Seg List" file or "Seg csv" file is loaded.
The command is valid only when the "Segment" file is loaded.
Return Format
The query returns the trigger mode of the IQ data segment. For example, SAME.
Example :IQ:TRIG:SEGM:MODE SAME
:IQ:TRIG:SEGM:MODE?
Related
Commands
[:SOURce]:IQ:TRIGger:SEGMent:EXECute
[:SOURce]:IQ :TRIGger:SEGMent:NEXT
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg3c.png)
RIGOL Chapter 2 Command System
2- 40 DSG800 Programming Guide
[:SOURce]:IQ :TRIGger:SEGMent:NEXT
Syntax [:SOURce]:IQ:TRIGger:SEGMent:NEXT <value>
[:SOURce]:IQ:TRIGger:SEGMent:NEXT?
Description Set the number of the next segment of the wavetable.
Query the number of the next segment of the wavetable.
Parameter
Name
Type
Range
Default
<value> 0 Integer 0 to 63
Explanation The upper limit of <value> is determined by the total number of wavetable
segments of the "Segment" file currently loaded.
The number of the next segment of the wavetable increases by 1 automatically
each time a next segment trigger is executed by sending the
[:SOURce]:IQ:TRIGger:SEGMent:EXECute command.
The command is valid only when the "Segment" file is loaded.
Return Format The query returns the number of the next segment of the wavetable. For example, 2.
Example :IQ:TRIG:SEGM:NEXT 2
:IQ:TRIG:SEGM:NEXT?
Related
Commands
[:SOURce]:IQ:TRIGger:SEGMent:EXECute
[:SOURce]:IQ:TRIGger:SEGMent:MODE
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg3d.png)
Chapter 2 Command System RIGOL
DSG800 41 2-Programming Guide
[:SOURce]:LEVel Command Subsystem
Command List:
[:SOURce]:LEVel
[:SOURce]:LEVel:STEP
[:SOURce]:LEVel
Syntax [:SOURce]:LEVel <value>
[:SOURce]:LEVel?
Description Set the RF output amplitude.
Query the RF output amplitude.
Parameter
Name
Type
Range
Default
<value> - - Real 110dBm to 20dBm 110dBm
Explanation When <value> is set in "Number" form (for example, 2), the default unit is
dBm. In addition, <value> can also be set in "Number + Unit" form (for
example, 2dBm); at this point, the amplitude displayed in the RF signal
generator interface is related to the setting of Level Unit.
— " " When the level unit is dBm , 2.00dBm is displayed;
— " " When the level unit is dBmV , 48.99dBmV is displayed;
— " " When the level unit is dBuV , 108.99dBuV is displayed;
— " " When the level unit is Volts , 281.50mV is displayed;
— " When the level unit is Watts", 1.58mW is displayed.
The default unit of return value isthe dBm.
After the output amplitude is set, you can rotate the knob to modify the RF
amplitude at the current step. At this point, you can set and query the current
step using the [:SOURce]:LEVel:STEP command.
Return Format The quer the RF output amplitudey returns . For example, 2.00.
Example :LEV 2dBm*/ 2dBm /*Set the of the RF signal amplitude to
:LEV Query 2.00*/? /* the amplitude of the RF signal and the query returns
Related
Command
[:SOURce]:LEVel:STEP
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg3e.png)
RIGOL Chapter 2 Command System
2- 42 DSG800 Programming Guide
[:SOURce]:LEVel:STEP
Syntax [:SOURce]:LEVel:STEP <value>
[:SOURce]:LEVel:STEP?
Description Set the RF output amplitude step.
Query the RF output amplitude step.
Parameter Name Type Range Default
<value>
Real
0 .01dB to 100dB
10dB
Explanation When <value> is set in "Number" form, the default unit is dB. Besides, <value>
can also be set in " Number + Unit" form; for example, 20dB.
The default unit of the return value is dB.
After the output amplitude step is set, you can rotate the knob to modify the
output amplitude at the current step. At this point, you can query or set the
output amplitude using the [:SOURce]:LEVel command.
Return Format The query returns the RF output amplitude step. For example, 20.00.
Example :LEV:STEP 20
:LEV:STEP?
Related
Command
[:SOURce]:LEVel
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg3f.png)
Chapter 2 Command System RIGOL
DSG800 43 2-Programming Guide
[:SOURce]:LFOutput Command Subsystem
Command List:
[:SOURce]:LFOutput:FREQuency
[:SOURce]:LFOutput:LEVel
[:SOURce]:LFOutput:SHAPe
[:SOURce]:LFOutput[:STATe]
[:SOURce]:LFOutput:FREQuency
Syntax [:SOURce]:LFOutput:FREQuency <value>
[:SOURce]:LFOutput:FREQuency?
Description Set the frequency of the LF output signal.
Query the frequency of the LF output signal.
Parameter
Name
Type
Range
Default
<value> Real 0Hz to 2 e)/0Hz to 20kHz (S00kHz (Sin quare) 1kHz
Explanation When <value> <value> is set in "Number" form, the default unit is Hz. Besides, can
also be set in "Number + Unit" form; for example, 2kHz.
Return Format The query returns the frequency of the LF output signal. For example, 2.00000kHz.
Example :LFO:FREQ 2kHz
:LFO:FREQ?
[:SOURce]:LFOutput:LEVel
Syntax [:SOURce]:LFOutput:LEVel <value>
[:SOURce]:LFOutput:LEVel?
Description Set the amplitude of the LF output signal.
Query the amplitude of the LF output signal.
Parameter
Name
Type
Range
Default
<value>
Real
0 V to 3V
500mV
Explanation When <value> is set in "Number" form, the default unit is V. Besides, <value>
can also be set in "Number + Unit" form; for example, 2V.
The default unit of the return value is V.
Return Format The query returns the amplitude of the LF output signal. For example, 2.00.
Example :LFO:LEV 2
:LFO:LEV?
![](https://manualstech.ams3.cdn.digitaloceanspaces.com/html/nl/rigol/dsg836a/html/bg47.png)
Chapter 2 Command System RIGOL
DSG800 51 2-Programming Guide
[:SOURce]:PULM Command Subsystem
Command List[3]:
[:SOURce]:PULM:MODE
[:SOURce]:PULM: OUT:STATe
[:SOURce]:PULM:PERiod
[:SOURce]:PULM:PERiod:STEP
[:SOURce]:PULM:POLarity
[:SOURce]:PULM:SOURce
[:SOURce]:PULM:STATe
[:SOURce]:PULM:TRAin:LIST:COUNt
[:SOURce]:PULM:TRAin:LIST:GET
[:SOURce]:PULM:TRIGger:DELay
[:SOURce]:PULM DELay:STEP:TRIGger:
[:SOURce]:PULM:TRIGger:EXTernal:GATE:POLarity
[:SOURce]:PULM:TRIGger:EXTernal:SLOPe
[:SOURce]:PULM:TRIGger:MODE
[:SOURce]:PULM:WIDTh
[:SOURce]:PULM:WIDTh:STEP
[:SOURce]:PULM:MODE
Syntax [:SOURce]:PULM:MODE SINGle|TRAin
[:SOURce]:PULM:MODE?
Description Set the pulse modulation mode.
Query the pulse modulation mode.
Parameter
Name
Type
Range
Default
SINGle |TRAin
Discrete
SINGle |TRAin
SINGle
Explanation SINGle: set the pulse type to "single" and enable the single pulse modulation
mode.
TRAIn: set the pulse type to "Train" and enable the train pulse modulation
mode.
When "Ext" modulation source is selected, this command is invalid.
Return Format The query returns SINGLE . or TRAIN
Example :PULM:MODE SING
:PULM:MODE?
Related
Command
[:SOURce]:PULM:SOURce
Note[3] : To use the commands related to lse Generator", you need to install the "Pulse Modulation" and "Pu
DSG800- PUM option; to use the related commands of "Train", you need to install the DSG800- PUG option; otherwise,
the command settings are invalid. For the installation methods of the option, refer to
DSG800 User's Guide
.
Especificaciones del producto
Marca: | Rigol |
Categoría: | Generador |
Modelo: | DSG836A |
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