Rigol DG1022Z, DG1032Z Performance Verification Manual

RIGOL

Performance Verification Guide

DG1000Z Series

Function/Arbitrary Waveform Generator

Oct. 2016

RIGOL TECHNOLOGIES, INC.

RIGOL

Guaranty and Declaration

Copyright

© 2014 RIGOL TECHNOLOGIES, INC. All Rights Reserved.

Trademark Information

RIGOL is a registered trademark of RIGOL TECHNOLOGIES, INC.

Publication Number

PVB09104-1110

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 losses caused by either incidental or consequential 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, or 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 ISO9001:2008 standard and the ISO14001:2004 standard.

Other international standard conformance certification is in progress.

Contact Us

If you have any problem or requirement when using our products or this manual, please contact RIGOL .

E-mail: [email protected]

Websites: www.rigol.com

DG1000Z Performance Verification Guide I

RIGOL

General Safety Summary

Please review the following safety precautions carefully before putting the instrument into operation so as to avoid any personal injury or damage to the instrument and any product connected to it. To prevent potential hazards, please use the instrument only specified by this manual.

Use Proper Power Cord.

Only the 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, it is essential to connect the earth terminal of power cord to the

Protective Earth terminal before any inputs or outputs.

Connect the Probe Correctly.

If a probe is used, do not connect the ground lead to high voltage since it has the isobaric electric potential as ground.

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.

Use Proper Overvoltage Protection.

Make sure that no overvoltage (such as that caused by a thunderstorm) can reach the product, or else the operator might expose to danger of electrical shock.

Do Not Operate Without Covers.

Do not operate the instrument with covers or panels removed.

Do Not Insert Anything into the Holes of Fan.

Do not insert anything into the holes of the fan to avoid damaging the instrument.

Use Proper Fuse.

Please use the specified fuses.

II DG1000Z Performance Verification Guide

RIGOL

Avoid Circuit or Wire Exposure.

Do not touch exposed junctions and components when the unit is powered.

Do Not Operate With Suspected Failures.

If you suspect damage occurs to the instrument, have it inspected by qualified service personnel before further operations.

Any maintenance, adjustment or replacement especially to circuits or accessories must be performed by RIGOL authorized personnel.

Keep Well Ventilation.

Inadequate ventilation may cause increasing of temperature or damages to the device. So please keep well ventilated and inspect the intake and fan regularly.

Do Not Operate in Wet Conditions.

In order to avoid short circuiting to the interior of the device or electric shock, please do not operate in a humid environment.

Do Not Operate in an Explosive Atmosphere.

In order to avoid damages to the device or personal injuries, it is important to operate the device away from an explosive atmosphere.

Keep Product Surfaces Clean and Dry.

To avoid the influence of dust and/or moisture in air, please keep the surface of device clean and dry.

Electrostatic Prevention.

Operate in an electrostatic discharge protective area environment to avoid damages induced by static discharges. Always ground both the internal and external conductors of the cable to release static before connecting.

Proper Use of Battery.

If a battery is supplied, it must not be exposed to high temperature or in contact with fire. Keep it out of the reach of children. Improper change of battery (note: lithium battery) may cause explosion. Use RIGOL specified battery only.

DG1000Z Performance Verification Guide III

RIGOL

Handling Safety.

Please handle with care during transportation to avoid damages to buttons, knob interfaces and other parts on the panels.

IV DG1000Z Performance Verification Guide

RIGOL

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.

DG1000Z Performance Verification Guide V

RIGOL

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 qualifiziertes Kundendienstpersonal 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 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 RIGOLangegebenenAkkus.

Sicherer Transport.

Transportieren Sie das Gerät sorgfältig (Verpackung!), um Schäden an

Bedienelementen, Anschlüssen und anderen Teilen zu vermeiden.

VI DG1000Z Performance Verification Guide

RIGOL

Document Overview

This manual is used to guide users to correctly test the performance specifications of

DG1000Z series function/arbitrary waveform generator. The performance verification test mainly verifies whether DG1000Z series function/arbitrary waveform generator can work normally and is within specifications.

Main topics in this Manual:

Chapter 1 Test Overview

This chapter introduces the preparations before the performance verification test, the recommended test devices, the test result record, the test notices and the related information of the technical parameters.

Chapter 2 Performance Verification Test

This chapter introduces the test method, procedures and limits of each performance specification in details.

Appendix

The appendix provides the test results record forms and performance specifications of DG1000Z series function/arbitrary waveform generator.

Format Conventions in this Manual:

1.

Button

The front-panel key is denoted by the format of “Button Name (Bold) + Text

Box” in the manual, for example, Utility denotes the “Utility” key.

2.

Menu

The menu is denoted by the format of “Menu Word (Bold) + Character Shading” in the manual, for example, System denotes the “System” menu item under

Utility.

3.

Operation Step

The next step of the operation is denoted by an arrow “  ” in the manual. For example, Utility  System denotes pressing Utility at the front panel and then pressing System.

DG1000Z Performance Verification Guide VII

RIGOL

Content Conventions in this Manual:

DG1000Z series function/arbitrary waveform generator includes the following models.

Unless otherwise noted in this manual, DG1062Z is taken as an example to illustrate the performance verification test methods of DG1000Z series.

Model

DG1062Z

Number of Channels

2

Max. Output Frequency

60MHz

DG1032Z

DG1022Z

2

2

30MHz

25MHz

VIII DG1000Z Performance Verification Guide

Contents RIGOL

Contents

Guaranty and Declaration ......................................................................... I

General Safety Summary ........................................................................ II

Allgemeine Sicherheits Informationen ..................................................... V

Document Overview .............................................................................. VII

Chapter 1 Test Overview .................................................................... 1-1

Test Preparations ................................................................................... 1-1

Recommended Test Devices ................................................................... 1-1

Test Result Record ................................................................................. 1-2

Test Notices .......................................................................................... 1-2

Technical Parameters ............................................................................. 1-3

Chapter 2 Performance Verification Test ............................................ 2-1

Frequency Accuracy Test ........................................................................ 2-2

AC Amplitude Accuracy Test ................................................................... 2-4

DC Offset Accuracy Test ......................................................................... 2-7

AC Flatness Test .................................................................................... 2-9

Harmonic Distortion Test ....................................................................... 2-12

Spurious Signal Test ............................................................................. 2-15

Rise/Fall Time Test ............................................................................... 2-18

Overshoot Test ..................................................................................... 2-20

Appendix .................................................................................................. 1

Appendix A: Test Result Record Form ......................................................... 1

Appendix B: Performance Specifications ..................................................... 9

DG1000Z Performance Verification Guide IX

Chapter 1 Test Overview

RIGOL

Chapter 1 Test Overview

Test Preparations

Before performing the test, make sure that the instrument is within the calibration period (the recommended calibration period is 1 year) and has been warmed up for at least 30 minutes under the specified operation temperature (18 ℃ to 28 ℃ ).

Recommended Test Devices

It is recommended that you use the test devices listed in the table below or other test devices whose performance specifications satisfy the “Performance Requirement” listed in the table below to test the performance specifications of the DG1000Z series.

Table 1-1 Recommended test devices

Recommended

Device Performance Requirement

Instrument

Frequency Counter

>10MHz

Accuracy: 0.1ppm

Digital Multimeter 6 1 /

2

digits

Power Meter

-30dBm to +20dBm

Accuracy: ±0.02dB

Spectrum Analyzer

Resolution: 0.01dB

Minimum resolution bandwidth is

100Hz

Bandwidth: 500MHz

Agilent 53131A

RIGOL

Agilent E4418B

RIGOL

DM3068

DSA815

Oscilloscope

Rise/Fall time measurement function

Overshoot measurement function

RIGOL

Connecting Cable BNC (m)-BNC (m)

--

Connecting Cable BNC (m)-Dual banana plug (m)

--

DS4000 series

DG1000Z Performance Verification Guide 1-1

RIGOL


50Ω Load

Power Sensor

Power Sensor

Connecting Cable

Adaptor

Adaptor

50Ω/1W

-30dBm to +20dBm

Used to connect the power meter and power sensor

N (f)-BNC (m)

BNC (f)-N (m)

Test Result Record

--

Agilent N8482A

--

--

--

Record and keep the test results of each test item. The test result record forms, which provide all the test items and the corresponding performance specification limits as well as spaces for users to record the test results, are provided in

“Appendix A: Test Result Record Form” of this manual.

Tip:

It is recommended that you photocopy the test result record form before each test.

During the test process, record the test results on the copies so that the forms can be used repeatedly.

Test Notices

To achieve optimum test effect, all the test procedures should follow the following recommendations.

1) Make sure that the environment temperature is between 18 ℃ and 28 ℃ and every test is performed under the specified operation temperature (18 ℃ to

28 ℃ ).

2) Before performing each test, make sure that the instrument has been warmed up for at least 30 minutes.

3) Before performing each test, restore the instrument to factory setting.

1-2 DG1000Z Performance Verification Guide


RIGOL

Technical Parameters

Chapter 2 of this manual provides the corresponding specification of each test item.

Besides, “Appendix B: Performance Specifications” provides the detailed

performance specifications of DG1000Z series.


Chapter 2 Performance Verification Test

RIGOL

Chapter 2 Performance Verification Test

This chapter introduces the performance verification test methods of DG1000Z series function/arbitrary waveform generator by taking CH1 of DG1062Z as an example.

The test methods are also applicable to CH2.

The test items include:



Frequency Accuracy Test



AC Amplitude Accuracy Test



DC Offset Accuracy Test



AC Flatness Test



Harmonic Distortion Test



Spurious Signal Test



Rise/Fall Time Test



Overshoot Test


RIGOL


Frequency Accuracy Test

Specification:

Frequency characteristic

Accuracy ±1ppm of setting value [1] , 18 ℃ to 28 ℃

Note [1] : ppm denotes one part per million. For example, if the setting frequency is 1MHz and the actual output frequency is between 0.999 999MHz (-1ppm) and 1.000 001MHz (+1ppm), the instrument is up to the specification requirement and the test passes.

Test Procedures:

1.

Make sure that the environment temperature is between 18 ℃ and 28 ℃ and

DG1000Z has been warmed up for at least 30 minutes. Connect the channel output terminal (take CH1 as an example; the test method is also applicable to

CH2) of DG1000Z with the signal input terminal of the frequency counter using a

dual-BNC cable as shown in Figure 2-1.

DG1000Z Series Frequency Counter

◎

Figure 2-1 Connect DG1000Z and the Frequency Counter

2.

Turn on the frequency counter and set its output impedance to 1MΩ.

3.

Turn on DG1000Z. Press Utility  Set To Default  OK to restore DG1000Z to the factory setting.

4.

Set DG1000Z: a) Set the output waveform of CH1 to a sine waveform with 1MHz frequency and 1Vpp amplitude. b) Press Output1 to turn on the output of CH1.



RIGOL

5.

Record the reading of the frequency counter and judge whether the reading is between 0.999 999MHz and 1.000 001MHz.

6.

Set CH1 of DG1000Z to output square, ramp and pulse waveforms (the frequencies are 1MHz and the amplitudes are 1Vpp) respectively. Record the readings of the frequency counter respectively and judge whether the readings are between 0.999 999MHz and 1.000 001MHz.

7.

Repeat steps 1 to 6 to test the frequency accuracy of CH2 and record the test results.

Test Record Form:

Waveform

Setting

Value

Measurement

Value

Specification Pass/Fail

Sine

Square

Ramp

Pulse

Frequency:

1MHz

Amplitude:

1Vpp

0.999 999MHz to

1.000 001MHz


RIGOL


AC Amplitude Accuracy Test

Specification:

Output Characteristic

Amplitude (into 50Ω)

Accuracy

Typical (1kHz Sine, 0V

DC

Offset, >10mVpp, Auto)

±1% of setting value ±1mV


1.


DG1000Z has been warmed up for at least 30 minutes. Connect the 50Ω load to the channel output terminal (take CH1 as an example; the test method is also applicable to CH2) of DG1000Z; connect the 50Ω load and the voltage input terminals of the digital multimeter using a BNC-Dual banana plug connecting

cable as shown in Figure 2-2.

DG1000Z Series Digital Multimeter

◎ ◎

◎ ◎

◎

50Ω Load

Figure 2-2 Connect DG1000Z and the Digital Multimeter via a 50Ω Load

2.

Turn on the multimeter, select the ACV measurement function and set the range to “Auto”.

3.


4.

Set DG1000Z: a) Set the output impedance of CH1 to 50Ω (press Utility  Channel Set 

Output Set  Imped and select “Load”).



RIGOL b) Set the output waveform of CH1 to a sine waveform with 1kHz frequency,

20mVpp amplitude and 0V

DC

offset. c) Press Output1 to turn on the output of CH1.

5.

Record the reading of the multimeter and judge whether it is within the

specification (“Amplitude Output Value (Vrms)” in Table 2-1) range.

6.

Keep the output impedance of CH1 of DG1000Z at 50Ω and the output waveform of CH1 as a sine waveform with 1kHz frequency and 0V

DC

offset. Set the output amplitude of CH1 to 100mVpp, 500mVpp, 1Vpp, 5Vpp and 10Vpp respectively. Record the readings of the multimeter respectively and judge whether the readings are within the specification (“Amplitude Output Value

(Vrms)” in Table 2-1) range.

Table 2-1 Amplitude output values (Vrms) of AC amplitude accuracy test

Amplitude

Setting

Value

(Vpp)

Allowed

Error (Vpp) [1]

Amplitude Output

Value (Vpp)

Amplitude Output Value

(Vrms) [2]

20mVpp ±1.2mVpp

100mVpp ±2mVpp

500mVpp ±6mVpp

1Vpp ±11mVpp

18.8mVpp to 21.2mVpp 6.6mVrms to 7.5mVrms

98mVpp to 102mVpp 34.7mVrms to 36.1mVrms

494mVpp to 506mVpp

0.989Vpp to 1.011Vpp

174.7mVrms to 178.9mVrms


5Vpp ±51mVpp 4.949Vpp to 5.051Vpp 1.75Vrms to 1.7861Vrms

10Vpp ±101mVpp 9.899Vpp to 10.101Vpp 3.5Vrms to 3.5717Vrms

Note [1] : “Allowed Error” is calculated from the specification “±1% of setting value ±1mVpp”.

Note [2] : “Amplitude Output Value (Vrms)” is calculated from “Amplitude Output Value (Vpp)”.

The conversion relation between Vrms and Vpp is

V pp

=

2 2 V rms

.

7.

Repeat steps 1 to 6 to test the AC amplitude accuracy of CH2 and record the test results.


RIGOL



Amplitude

Setting Setting

Value

20mVpp

100mVpp

500mVpp

1Vpp

5Vpp

Frequency:

1kHz

Offset: 0V

DC

Impedance:

50Ω

10Vpp

Measurement

Value

Specification





1.75Vrms to 1.7861Vrms


Pass/Fail



RIGOL

DC Offset Accuracy Test

Specification:


Offset (into 50Ω)

Accuracy ±(1% of setting value + 5mV + 0.5% of amplitude)


1.




2.

Turn on the multimeter, select the DCV measurement function and set the range to “20V”.

3.


4.


Output Set  Imped and select “Load”). b) Set the output waveform of CH1 to a sine waveform with 1kHz frequency,

5Vpp amplitude and 0V

DC


5.

Record the reading of the multimeter and judge whether it is within the

specification (“Offset” in Table 2-2) range.

6.

Keep the output impedance of CH1 of DG1000Z at 50Ω and the output waveform of CH1 as a sine waveform with 1kHz frequency and 5Vpp amplitude.

Set the offset of the output waveform of CH1 to -2.5V

DC

, -1V

DC

, -500mV

DC

,

500mV

DC

, 1V

DC

and 2.5V

DC

respectively. Record the readings of the multimeter


RIGOL


respectively and judge whether the readings are within the specification

(“Offset” in Table 2-2) range.

Table 2-2 Offset limits of DC offset accuracy test

Offset Setting

Value

Amplitude

Setting Value

Allowed Error [1]

-2.5V

DC

±0.005V

DC

-1V

DC

-500mV

DC

0V

DC

500mV

DC

1V

DC

5Vpp

±0.020V

DC

±0.025V

DC

±0.030V

DC

±0.035V

DC

±0.040V

DC

Offset [2]

-2.505V

DC

to -2.495V

DC

-1.02V

DC

to -0.98V

DC

-0.525V

DC

to -0.475V

DC

-0.030V

DC

to 0.030V

DC

0.465V

DC

to 0.535V

DC

0.96V

DC

to 1.04V

DC

2.5V

DC

±0.055V

DC

2.445V

DC

to 2.555V

DC

Note [1] : “Allowed Error” is calculated from the specification “± (1% of setting value + 5 mV + 0.5% of amplitude)”.

Note [2] : Offset = offset setting value ± allowed error.

7.

Repeat steps 1 to 6 to test the DC offset accuracy of CH2 and record the test results.


Offset

Setting

Value

Setting

Measurement

Value

Specification Pass/Fail

-2.5V

DC

-2.505V

DC

to -2.495V

DC

-1V

DC

-500mV

DC

0V

DC

500mV

DC

1V

DC

2.5V

DC

Frequency:

1kHz

Amplitude:

5Vpp

Impedance:

50Ω

-1.02V

DC

to -0.98V

DC

-0.525V

DC

to -0.475V

DC

-0.030V

DC

to 0.030V

DC

0.465V

DC

to 0.535V

DC

0.96V

DC

to 1.04V

DC

2.445V

DC

to 2.555V

DC



RIGOL

AC Flatness Test

Specification:


Flatness

Typical (Sine, 2.5Vpp)

≤10MHz: ±0.1dB

≤60MHz: ±0.2dB


1.




2.


3.


Output Set  Imped and select “Load”). b) Set the output waveform of CH1 to a sine waveform with 1kHz frequency and 2.5Vpp amplitude. c) Press Output1 to turn on the output of CH1.

4.

Turn on the multimeter and select the ACV measurement function. Turn on the dBm operation function and set the reference resistance to 50Ω. Read the measurement value and take it as the reference power (P ref

).

Tip:

In this step, if the dBm operation function is not turned on, you can also calculate the reference power using the formula dBm

=

10

×

Log

10

[( V reading

2

/ R ref

) / 1 mW ]

according to the measurement value of


RIGOL


the multimeter.

Wherein,

V reading

is the measurement value of the multimeter.

5.

Calibrate the power meter: a) Connect the power sensor to the input terminal and [POWER REF] terminal of the power meter respectively. b) Press Zero/Cal  Zero  Cal. Turn on power reference after the calibration finishes and observe whether the measurement value of the power meter is a 0dBm, 50MHz signal. c) Turn off power reference.

6.

Disconnect DG1000Z and the multimeter. Connect the power sensor and the channel output terminal (take CH1 as an example; the test method is also applicable to CH2) of DG1000Z using a BNC (f)-N (m) adaptor, as shown in

Figure 2-3.

DG1000Z Series Power Meter

◎

Figure 2-3 Connect DG1000Z and the Power Meter

7.

Keep the output impedance of CH1 of DG1000Z at 50Ω. Set the output waveform of CH1 as a sine waveform with 5MHz frequency and 2.5Vpp amplitude. Set the frequency factor of the power meter to 5MHz, record the measurement value of the power meter and judge whether “measurement value-P ref

” is between -0.1dB and +0.1dB.

8.

Keep the output impedance of CH1 of DG1000Z at 50Ω. Set the output waveform of CH1 as a sine waveform with 10MHz frequency and 2.5Vpp



RIGOL amplitude. Set the frequency factor of the power meter to 10MHz, record the measurement value of the power meter and judge whether “measurement value-P ref


9.



10.



11.

Repeat steps 1 to 10 to test the AC flatness of CH2 and record the test results.


Frequency

Setting

Value

Setting

Measurement

Value

Calculation

Result [1]

Specification Pass/Fail

5MHz

10MHz

25MHz

30MHz

Amplitude:

2.5Vpp

Impedance:

50Ω

60MHz

Note [1] : Calculation result = Measurement value - P ref

.

±0.1dB

±0.2dB


RIGOL


Harmonic Distortion Test

Specification:

Sine Wave Spectrum Purity

Typical (0dBm)

DC to 10MHz (include 10MHz): <-65dBc

Harmonic Distortion

10MHz to 30MHz (include 30MHz): <-55dBc

30MHz to 60MHz (include 60MHz): <-50dBc


1.



CH2) of DG1000Z with the signal input terminal of the spectrum analyzer using a

dual-BNC connecting cable and N-BNC adaptor as shown in Figure 2-4.

DG1000Z Series Spectrum Analyzer

◎

Figure 2-4 Connect DG1000Z and the Spectrum Analyzer

2.


3.


Output Set  Imped and select “Load”). b) Set the output waveform of CH1 to a sine waveform with 10MHz frequency,

0dBm amplitude and 0V

DC




RIGOL

4.

Turn on and set the spectrum analyzer: a) Set the reference level to 10dBm and input attenuation to 20dB. b) Set the start frequency to 5MHz and stop frequency to 30MHz. c) Set the resolution bandwidth to 3kHz.

5.

Use the cursor function to make measurements and record the measurement values of the base waveform and 2 nd order harmonic. Calculate [1] the harmonic distortion and judge whether it is less than -65dBc.

6.

Keep the output impedance of CH1 of DG1000Z at 50Ω. Set the output waveform of CH1 as a sine waveform with 30MHz frequency, 0dBm amplitude and 0V

DC

offset.

7.

Keep the reference level, input attenuation and resolution bandwidth of the spectrum analyzer as 10dBm, 20dB and 3kHz respectively. Set its start frequency to 20MHz and stop frequency to 70MHz.

8.


9.


DC

offset.

10.

Keep the input attenuation, reference level and resolution bandwidth of the spectrum analyzer as 20dB, 10dBm and 3kHz respectively. Set its start frequency to 50MHz and stop frequency to 150MHz.

11.


12.

Repeat steps 1 to 11 to test the harmonic distortion of CH2 and record the test results.

Note [1] : 2 nd order harmonic distortion = 2 nd order harmonic measurement value – base waveform


RIGOL


measurement value

For example, when the output waveform frequency of the channel is 10MHz, if the base waveform measurement value is 0.8dBm and the 2 nd order harmonic measurement value is -66.2dBm, the 2 nd order harmonic distortion = (-66.2) -0.8=-67dBc<-65dBc and the test result fulfills the specification requirement.


Frequency

Setting

Value

Setting

Measuremen t Value

Calculation

Result [1]


10MHz

Base waveform:

2 nd order harmonic:

<-65dBc

25MHz

30MHz

60MHz

Waveform:

Sine

Amplitude:

0dBm

Offset: 0V

DC

Base waveform:


Base waveform:


Base waveform:

2 nd order

<-55dBc

<-55dBc

<-50dBc harmonic:

Note [1] : Calculation result = 2th order harmonic measurement value - base waveform measurement value.



RIGOL

Spurious Signal Test

Specification:

Sine Wave Spectrum Purity (Typical 0dBm)

Spurious signal

(non-harmonic)

Typical (0dBm)

≤10MHz: <-70dBc

>10MHz: <-70dBc+6dB/octave [1]

Note [1] : 6 dBc/octave means that when the frequency doubles, the specification increases by 6 dBc. For example, when the output frequency of DG1000Z is 10MHz, the specification is <-70dBc and when the output frequency is 30MHz, the specification is <-70dBc+2×6dBc, namely <-58dBc.


1.



CH2) of DG1000Z with the RF input terminal of the spectrum analyzer using a

dual-BNC cable and N-BNC adaptor as shown in Figure 2-4.

2.


3.


Output Set  Imped and select “Load”). b) Set the output waveform of CH1 to a sine waveform with 5MHz frequency,

0dBm amplitude and 0V

DC

offset. d) Press Output1 to turn on the output of CH1.

4.

Turn on and set the spectrum analyzer: a) Set the reference level to 10dBm and input attenuation to 20dB. b) Set the start frequency to 0Hz and stop frequency to 30MHz. c) Set the resolution bandwidth to 1kHz. d) Set the peak offset to 3dB. e) Set the sweep mode to single.


RIGOL


5.

After the spectrum analyzer finishes a sweep, use Peak and the cursor function to measure the maximum spurious signal (except harmonics) and record the measurement result as A. Calculate the non-harmonic spurious signal (A-0dBm) and judge whether it is within the specification range.

6.


DC

offset.

7.

Keep the reference level, input attenuation, resolution bandwidth, peak offset and sweep mode of the spectrum analyzer as 10dBm, 20dB, 1kHz, 3dB and single respectively. Set its start frequency to 0MHz and stop frequency to

50MHz.

8.

Press Sweep/Trig  Single to perform a sweep.

9.

After the spectrum analyzer finishes a sweep, use Peak and the cursor function to measure the maximum spurious signal (except harmonics) and record the measurement result as A. Calculate the non-harmonic spurious signal (A-0dBm) and judge whether it is within the specification range.

10.


DC

offset.

11.


100MHz.

12.

Repeat steps 8 and 9.

13.


DC

offset.



RIGOL

14.


150MHz.

15.


16.


DC

offset.

17.


300MHz.

18.


19.

Repeat steps 1 to 18 to test the spurious signal (non-harmonic) of CH2 and record the test results.


Output

Frequency

Start

Frequency

Stop

Frequency

A A-0dBm Specification Pass/Fail

5MHz 0Hz 30MHz <-70dBc

10MHz 0Hz 50MHz <-70dBc

20MHz

25MHz

30MHz

60MHz

0Hz

0Hz

0Hz

0Hz

100MHz

150MHz

150MHz

300MHz

<-64dBc

<-58dBc

<-58dBc

<-40dBc


RIGOL


Rise/Fall Time Test

Specification:

Signal Characteristic

Square

Rise/Fall Time

Typical (1Vpp)

<10ns


1.



CH2) of DG1000Z with the signal input terminal of the oscilloscope using a

dual-BNC connecting cable as shown in Figure 2-5.

DG1000Z Series Oscilloscope

◎

Figure 2-5 Connect DG1000Z and the Oscilloscope

2.


3.


Output Set  Imped and select “Load”). b) Set the output waveform of CH1 to a square waveform with 1MHz frequency,

1Vpp amplitude and 0V

DC




RIGOL

4.

Turn on and set the oscilloscope: a) Set the vertical scale to 200mV/div. b) Set the horizontal time base to 1ns. c) Adjust the trigger level to a proper value. d) Set the input impedance to 50Ω. e) Turn on the rise time and fall time measurement functions.

5.

Set the edge type of the oscilloscope to rising edge, record the measurement result of the rise time and judge whether it is within the specification range.

6.

Set the edge type of the oscilloscope to falling edge, record the measurement result of the fall time and judge whether it is within the specification range.

7.

Repeat steps 1 to 6 to test the rise/fall time of CH2 and record the measurement results.


Waveform Setting Measurement Value Specification Pass/Fail

Square

Frequency: 1MHz

Amplitude: 1Vpp

Offset: 0V

DC

Rise Time

Fall Time

Typical (1Vpp)

<10ns


RIGOL


Overshoot Test

Specification:

Signal Characteristic

Square

Overshoot

Typical (100kHz, 1Vpp)

≤5%


1.



CH2) of DG1000Z with the signal input terminal of the oscilloscope using a

dual-BNC connecting cable as shown in Figure 2-5.

2.

Turn on DG1000Z. Press Utility  Set To Default  OK to restore DG1000Z to factory setting.

3.


Output Set  Imped and select “Load”). b) Set the output waveform of CH1 to a square waveform with 100kHz frequency, 1Vpp amplitude and 0V

DC


4.

Turn on and set the oscilloscope: a) Set the input impedance to 50Ω. b) Set the vertical scale to 200mV/div. c) Set the horizontal time base to 50ns. d) Adjust the trigger level to a proper value. e) Turn on the overshoot measurement function.

5.

Record the overshoot measurement value and judge whether it is within the specification range.



RIGOL

6.

Repeat steps 1 to 5 to test the overshoot of CH2 and record the measurement result.


Waveform Setting Measurement Value Specification Pass/Fail

Square

Frequency: 100kHz

Amplitude: 1Vpp

Offset: 0V

DC

Typical (100kHz,

1Vpp)

<5%


Appendix

RIGOL

Appendix

Appendix A: Test Result Record Form

RIGOL DG1000Z Series Function/Arbitrary Waveform Generator

Performance Verification Test Record Form

Model: Tested by:

Channel: CH1


Waveform

Setting

Value

Measurement

Value

Specification

Test Date:

Pass/Fail

Sine

Square

Ramp

Pulse

Frequency:

1MHz

Amplitude:

1Vpp

0.999 999MHz to

1.000 001MHz


Amplitude

Setting Setting

Measurement

Value

Value

20mVpp

100mVpp

500mVpp

1Vpp

5Vpp

Frequency:

1kHz

Offset: 0V

DC

Impedance:

50Ω

10Vpp [1]

Note [1] : Only applicable to DG1062Z.

Specification







Pass/Fail

DG1000Z Performance Verification Guide 1

RIGOL

Appendix


Offset

Measurement

Setting Setting

Value

Value

-2.5V

DC

-1V

DC

-500mV

DC

0V

DC

500mV

DC

1V

DC

Frequency:

1kHz

Amplitude:

5Vpp

Impedance:

50Ω

2.5V

DC


Frequency

Setting

Value

Setting

Measurement

Value

5MHz

10MHz

25MHz

30MHz [1]

Amplitude:

2.5Vpp

Impedance:

50Ω

60MHz [2]

Note [1] : Only applicable to DG1032Z and DG1062Z.


Specification

-2.505V

DC

to -2.495V

DC

-1.02V

DC

to -0.98V

DC

-0.525V

DC

to -0.475V

DC

-0.030V

DC

to 0.030V

DC

0.465V

DC

to 0.535V

DC

0.96V

DC

to 1.04V

DC

2.445V

DC

to 2.555V

DC

Pass/Fail

Calculation

Result


±0.1dB

±0.2dB

2 DG1000Z Performance Verification Guide

Appendix


Frequency

Measurement

Setting Setting

Value

Value

10MHz

Base waveform:


Base waveform:


25MHz

30MHz [1]

60MHz [2]

Waveform:

Sine

Amplitude:

0dBm

Offset:

0V

DC

Base waveform:


Base waveform:




Calculation

Result

RIGOL


<-65dBc

<-55dBc

<-55dBc

<-50dBc


RIGOL

Appendix


Output Start

Frequency Frequency

5MHz 0Hz

Stop

Frequency

30MHz


<-70dBc

10MHz

20MHz

0Hz

0Hz

50MHz

100MHz

<-70dBc

<-64dBc

0Hz

0Hz

150MHz

150MHz

<-58dBc

<-58dBc

25MHz

30MHz [1]

60MHz [2] 0Hz 300MHz <-40dBc




Waveform Setting Measurement Value Specification

Square

Frequency: 1MHz

Amplitude: 1Vpp

Offset: 0V

DC

Overshoot Test

Waveform Setting

Rise Time

Fall Time

Typical (1Vpp)

<10ns

Measurement Value Specification

Square

Frequency: 100kHz

Amplitude: 1Vpp

Offset: 0V

DC

Typical (100kHz,

1Vpp)

<5%

Pass/Fail

Pass/Fail


Appendix

RIGOL

Channel: CH2


Setting Measurement

Waveform

Value Value

Sine

Square

Ramp

Frequency:

1MHz

Amplitude:

1Vpp

Pulse


Amplitude

Setting

Value

Setting

Measurement

Value

20mVpp

100mVpp

500mVpp

1Vpp

5Vpp

Frequency:

1kHz

Offset: 0V

DC

Impedance:

50Ω

10Vpp [1]


Specification

0.999 999MHz to

1.000 001MHz

Specification







Pass/Fail

Pass/Fail


RIGOL

Appendix


Offset

Measurement

Setting Setting

Value

Value

-2.5V

DC

-1V

DC

-500mV

DC

0V

DC

500mV

DC

1V

DC

Frequency:

1kHz

Amplitude:

5Vpp

Impedance:

50Ω

2.5V

DC


Frequency

Setting

Value

Setting

Measurement

Value

5MHz

10MHz

25MHz

30MHz [1]

Amplitude:

2.5Vpp

Impedance:

50Ω

60MHz [2]



Specification

-2.505V

DC

to -2.495V

DC

-1.02V

DC

to -0.98V

DC

-0.525V

DC

to -0.475V

DC

-0.030V

DC

to 0.030V

DC

0.465V

DC

to 0.535V

DC

0.96V

DC

to 1.04V

DC

2.445V

DC

to 2.555V

DC

Pass/Fail

Calculation

Result


±0.1dB

±0.2dB


Appendix


Frequency

Measurement

Setting Setting

Value

Value

10MHz

Base waveform:


Base waveform:


25MHz

30MHz [1]

60MHz [2]

Waveform:

Sine

Amplitude:

0dBm

Offset:

0V

DC

Base waveform:


Base waveform:




Calculation

Result

RIGOL


<-65dBc

<-55dBc

<-55dBc

<-50dBc


RIGOL

Appendix


Output Start

Frequency Frequency

5MHz 0Hz

Stop

Frequency

30MHz


<-70dBc

10MHz

20MHz

0Hz

0Hz

50MHz

100MHz

<-70dBc

<-64dBc

0Hz

0Hz

150MHz

150MHz

<-58dBc

<-58dBc

25MHz

30MHz [1]

60MHz [2] 0Hz 300MHz <-40dBc




Waveform Setting Measurement Value Specification

Square

Frequency: 1MHz

Amplitude: 1Vpp

Offset: 0V

DC

Overshoot Test

Waveform Setting

Rise Time

Fall Time

Typical (1Vpp)

<10ns

Measurement Value Specification

Square

Frequency: 100kHz

Amplitude: 1Vpp

Offset: 0V

DC

Typical (100kHz,

1Vpp)

<5%

Pass/Fail

Pass/Fail


Appendix

RIGOL

Appendix B: Performance Specifications

Unless otherwise specified, all the specifications can be guaranteed if the following two conditions are met.

 The generator is within the calibration period and has performed self-calibration.

 The generator has been working continuously for at least 30 minutes under the specified temperature (18 ℃ ~28 ℃ ).

All the specifications are guaranteed unless those marked with “typical”.

Model

Channel

DG1022Z

2

Maximum Frequency 25MHz

Sample Rate 200MSa/s

DG1032Z

2

30MHz

DG1062Z

2

60MHz

Waveforms

Basic waveforms

Built-in Arbitrary

Waveforms

Sine, Square, Ramp, Pulse, Noise

160 kinds, including Sinc, Exponential Rise, Exponential

Fall, ECG, Gauss, HaverSine, Lorentz, Dual-Tone, etc.

Frequency Characteristics

Sine

Square

Ramp

Pulse

Harmonic

Noise (-3dB)

Arbitrary Waveform

Resolution

Accuracy

1μHz to 25MHz 1μHz to 30MHz 1μHz to 60MHz


1μHz to 500kHz 1μHz to 500kHz 1μHz to 1MHz



25MHz 30MHz 60MHz bandwidth bandwidth bandwidth


1μHz

±1ppm of the settings, 18 ℃ to 28 ℃


RIGOL

Sine Wave Spectrum Purity

Harmonic Distortion

Typical (0dBm)

DC-10MHz (included): <-65dBc

10MHz-30MHz (included): <-55dBc

30MHz-60MHz (included): <-50dBc

Total Harmonic

Distortion

<0.075% (10Hz-20kHz, 0dBm)

Spurious

(non-harmonic)

Phase Noise

Typical (0dBm)

≤10MHz: <-70dBc

>10MHz: <-70dBc+6dB/octave

Typical (0dBm, 10kHz deviation)

10MHz: <-125dBc/Hz

Signal Characteristics

Square

Rise/Fall Time

Typical (1Vpp)

<10ns

Overshoot

Duty Cycle

Non-symmetry

Jitter (rms)

Typical (100KHz, 1Vpp)

≤5%

0.01% to 99.99%

(limited by the current frequency setting)

1% of period+5ns

Typical (1MHz, 1Vpp, 50Ω)

≤5MHz: 2ppm+200ps

>5MHz: 200ps

Ramp

Linearity

Symmetry

Pulse

≤1% of peak output

(typical, 1kHz, 1Vpp, 100% Symmetry)

0% to 100%

Pulse Width

Duty Cycle

Leading/Trailing

16ns to 999.999 982 118ks


0.001% to 99.999%


≥10ns

10

Appendix

DG1000Z Performance Verification Guide

Appendix

RIGOL

Edge Time

Overshoot

Jitter (rms)

(limited by the current frequency and pulse width settings)

Typical (1Vpp)

≤5%

Typical (1Vpp)

≤5MHz: 2ppm+200ps

>5MHz: 200ps

Arb

Waveform Length

8pts to 2Mpts (16Mpts optional)

8pts to 8Mpts (16Mpts optional)

Vertical Resolution 14bits

Sample Rate 200MSa/s

Minimum Rise/Fall

Time

Jitter (rms)

Typical (1Vpp)

<10ns

Typical (1Vpp)

≤5MHz: 2ppm+200ps

Edit Method

Harmonic

Harmonic Order

Harmonic Type

>5MHz: 200ps

Edit Points, Edit Block, Insert Waveform

≤8

Even, Odd, All, User

Harmonic Amplitude can be set for all harmonics

Harmonic Phase can be set for all harmonics

Output Characteristics

Amplitude (into 50 Ω)

Range

≤10MHz: 1.0mVpp to 10Vpp

≤30MHz: 1.0mVpp to 5.0Vpp

≤60MHz: 1.0mVpp to 2.5Vpp

Accuracy

Flatness

Units

Resolution

Typical (1kHz Sine, 0V Offset, >10mVpp, Auto)

±1% of setting ± 1mV

Typical (Sine 2.5Vpp)

≤10MHz: ±0.1dB

≤60MHz: ±0.2dB

Vpp, Vrms, dBm

0.1mVpp or 4digits


RIGOL

Appendix

Offset (into 50 Ω)

Range (Peak ac+dc) ±5Vpk ac+dc

Accuracy ±(1% of setting+5mV+0.5% of amplitude)

Waveform Output

Impedance 50Ω (typical)

Protection

Short-circuit protection, automatically disable waveform output when overload occurs

Modulation Characteristics

Modulation Type

AM

Carrier Waveform

Source

AM, FM, PM, ASK, FSK, PSK, PWM

Sine, Square, Ramp, Arb (except DC)

Internal/External

Modulating Waveform Sine, Square, Ramp, Noise, Arb

Depth 0% to 120%

Modulating Frequency 2mHz to 1MHz

FM

Carrier Waveform

Source



PM


Internal/External

Carrier Waveform

Source


Internal/External


Phase Deviation 0° to 360°


ASK

Carrier Waveform Sine, Square, Ramp, Arb (except DC)

Source Internal/External

Modulating Waveform Square with 50% duty cycle

Key Frequency

FSK

2mHz to 1MHz

Carrier Waveform

Source


Internal/External


Appendix

RIGOL


Key Frequency 2mHz to 1MHz

PSK

Carrier Waveform

Source


Internal/External


Key Frequency

PWM

2mHz to 1MHz

Carrier Waveform

Source

Modulating

Waveforms

Pulse

Internal/External

Sine, Square, Ramp, Noise, Arb

Width Deviation 0% to 100% of Pulse Width


[Mod/Trig/FSK/Sync] Input

Input Range 75mVRMS to ±5Vac+dc

Input Bandwidth 50kHz

Input Impedance 10kΩ

Burst Characteristics

Carrier Waveform Sine, Square, Ramp, Pulse, Noise, Arb (except DC)

Carrier Frequency

Burst Count

Start/Stop Phase

2mHz to 25MHz 2mHz to 30MHz

1 to 1,000,000 or Infinite

0° to 360°, 0.1° resolution

2mHz to 60MHz

Internal Period

Gated Source

Trigger Source

Trigger Delay

1μs to 500s

External Trigger

Internal, External or Manual

0ns to 100s

Sweep Characteristics

Carrier Waveform

Type


Linear, Log or Step

Direction Up/Down

Start/Stop Frequency Consistent with the upper/lower limit of the frequency of


RIGOL

Appendix

Sweep Time

Hold/Return Time

Trigger Source

Mark the carrier waveform

1ms to 500s

0ms to 500s

Internal, External or Manual

Falling edge of the Sync signal (programmable)

Counter

Function

Frequency, Period, Positive/Negative Pulse Width,

Duty Cycle

Frequency Resolution 7 digits/second (Gate Time =1s)

Frequency Range 1μHz to 200MHz

Period Measurement Measurement Range 5ns to 16 days

Voltage Range and Sensitivity (Not modulation signal)

DC Coupling

DC Offset Range

1μHz to 100MHz

±1.5Vdc

50mVRMS to ±2.5Vac+dc

100MHz to 200MHz 100mVRMS to ±2.5Vac+dc

AC Coupling

Input Signal Range

Input Adjustment

Input Trigger

1μHz to 100MHz 50mVRMS to ±2.5Vpp

100MHz to 200MHz 100mVRMS to ±2.5Vpp

Pulse Width and Duty Cycle Measurement

Frequency/Amplitude

Range

1μHz to 25MHz

50mVRMS to

±2.5Vac+dc

Pulse Width

Minimum

Resolution

≥20ns

5ns

Duty Cycle

Input Characteristics

Range (Display) 0% to 100%

DC Coupling

Breakdown Voltage ±7Vac+dc

Impedance=

1MΩ

Coupling

HF Suppression

AC DC

ON: input bandwidth=250kHz;

OFF: input bandwidth=200MHz

Trigger Level Range -2.5V to +2.5V

Trigger Sensitivity

Range

0% (about 140mV hysteresis voltage) to 100% (about 2mV hysteresis voltage)


Appendix

Gate Time

GateTime1

GateTime2

GateTime3

GateTime4

1.310ms

10.48ms

166.7ms

1.342s

GateTime5

GateTime6

10.73s

>10s

Trigger Characteristics

Trigger Input

Level

Slope

Pulse Width

TTL-compatible

Rising or falling (optional)

>100ns

Latency

Sweep: <100ns (typical)

Burst: <300ns (typical)

Trigger Output

Level

Pulse Width

TTL-compatible

>60ns (typical)

Maximum Frequency 1MHz

Two-channel Characteristics - Phase Offset

Range 0° to 360°

Waveform Phase

Resolution

0.03°

Clock Reference

External Reference Input

Lock Range 10MHz±50Hz

Level

Lock Time

250mVpp to 5Vpp

<2s

Impedance (typical) 1kΩ, AC coupling

Internal Reference Output

Frequency

Level

10MHz±50Hz

3.3Vpp


RIGOL

15

RIGOL

16

Appendix

Impedance (typical) 50Ω, AC coupling

Sync Output

Level

Impedance

TTL-compatible

50Ω, nominal value

Overvoltage Protection

Overvoltage protection will take effect once any of the following two conditions is met:

 The amplitude setting in the generator is greater than 2Vpp or the output offset is greater than |2V

DC

|, the input voltage is greater than

±11.5×(1±5%)V (<10kHz).

 The amplitude setting in the generator is lower than or equal to 2Vpp or the output offset is lower than or equal to |2V

DC

|, the input voltage is greater than

±3.5×(1±5%)V (<10kHz).

General Specifications

Power

Power Voltage

Power Consumption

Fuse

Display

Type

Resolution

Color

Environment

100V to 240V (45Hz to 440Hz)

Less than 40W

250V, T3.15A

3-inch TFT LCD

320 Horizontal×RGB×240 Vertical Resolution

16M color

Temperature Range

Cooling Method

Humidity Range

Altitude

Operating: 0 ℃ to 50 ℃

Non-Operating: -40 ℃ to 70 ℃

Cooling by fans compulsively

Less than 30 ℃ : ≤95% Relative Humidity (RH)

30 ℃ to 40 ℃ : ≤75% Relative Humidity (RH)

40 ℃ to 50 ℃ : ≤45% Relative Humidity (RH)

Operating: Less than 3000 meters

Non-Operating: Less than 15,000 meters


Appendix

Mechanical

Dimensions

(W×H×D)

261.5mm×112mm×318.4mm

Weight

Interfaces

IP Protection

Calibration

Interval without package: 3.2kg with package: 4.5kg

USB Host, USB Device, LAN

IP2X

Recommend calibration interval is one year

Authentication Information

In line with

EN61326-1:2006

EMC

Electrical Safety

IEC 61000-3-2:2000

IEC 61000-4-3:2002

±4.0kV (Contact Discharge)

±4.0kV (Air Discharge)

3V/m (80MHz to 1GHz)

3V/m (1.4GHz to 2GHz)

1V/m (2.0GHz to 2.7GHz)

IEC 61000-4-4:2004 1kV power lines

IEC 61000-4-5:2001

0.5kV (Phase to Neutral)

0.5kV (Phase to PE)

1kV (Neutral to PE)

IEC 61000-4-6:2003 3V, 0.15-80MHz

EC 61000-4-11:2004

Voltage dip:

0%UT during half cycle

0%UT during 1 cycle

70%UT during 25 cycle

Short interruption:

In line with

USA: UL 61010-1:2012

0%UT during 1 cycle

Canada: CAN/CSA-C22.2 No. 61010-1-2012

EN 61010-1:2010

RIGOL


Rigol DG1022Z, DG1032Z Performance Verification Manual

RIGOL

Performance Verification Guide

DG1000Z Series

Function/Arbitrary Waveform Generator

Oct. 2016

RIGOL TECHNOLOGIES, INC.

Guaranty and Declaration

Copyright

Trademark Information

Publication Number

Notices

Product Certification

Contact Us

General Safety Summary

Allgemeine Sicherheits Informationen

Document Overview

Contents

Chapter 1 Test Overview

Test Preparations

Recommended Test Devices

Test Result Record

Test Notices

Technical Parameters

Chapter 2 Performance Verification Test

Frequency Accuracy Test

AC Amplitude Accuracy Test

DC Offset Accuracy Test

AC Flatness Test

Harmonic Distortion Test

Spurious Signal Test

Rise/Fall Time Test

Overshoot Test

Appendix

Appendix A: Test Result Record Form

Appendix B: Performance Specifications

Related manuals

Table of contents

Rigol DG1022Z, DG1032Z Performance Verification Manual

RIGOL

Performance Verification Guide

DG1000Z Series

Function/Arbitrary Waveform Generator

Oct. 2016

RIGOL TECHNOLOGIES, INC.

Guaranty and Declaration

Copyright

Trademark Information

Publication Number

Notices

Product Certification

Contact Us

General Safety Summary

Allgemeine Sicherheits Informationen

Document Overview

Contents

Chapter 1 Test Overview

Test Preparations

Recommended Test Devices

Test Result Record

Test Notices

Technical Parameters

Chapter 2 Performance Verification Test

Frequency Accuracy Test

AC Amplitude Accuracy Test

DC Offset Accuracy Test

AC Flatness Test

Harmonic Distortion Test

Spurious Signal Test

Rise/Fall Time Test

Overshoot Test

Appendix

Appendix A: Test Result Record Form

Appendix B: Performance Specifications

Related manuals

Rigol

DG1000Z Series

Rigol

DG1032Z

Rigol

DG1000Z Series

Rigol

DG1032Z

Rigol

DG1062Z

Rigol

DG1032Z

Rigol

PHA_UserGuide_CN&EN

Table of contents