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AWG5200 Series

Arbitrary Waveform Generators Specifications and Performance Verification

This manual contains specifications and performance verification procedures for the AWG5200 Series Arbitrary Waveform Generators.


이 매뉴얼은 다음에 적용됩니다.:

AWG5202, AWG5204, AWG5208

  • 매뉴얼 타입: 성능 확인
  • 부품 번호: 077133502
  • 릴리즈 날짜:
  • Revision: Rev B

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AWG5200 Series
IMPORTANT SAFETY INFORMATION
PREFACE
SPECIFICATIONS
PERFORMANCE VERIFICATION PROCEDURES

Important safety information

This manual contains information and warnings that must be followed by the user for safe operation and to keep the product in a safe condition.

To safely perform service on this product, see the Service safety summary that follows the General safety summary.

General safety summary

Use the product only as specified. Review the following safety precautions to avoid injury and prevent damage to this product or any products connected to it. Carefully read all instructions. Retain these instructions for future reference.

This product shall be used in accordance with local and national codes.

For correct and safe operation of the product, it is essential that you follow generally accepted safety procedures in addition to the safety precautions specified in this manual.

The product is designed to be used by trained personnel only.

Only qualified personnel who are aware of the hazards involved should remove the cover for repair, maintenance, or adjustment.

Before use, always check the product with a known source to be sure it is operating correctly.

This product is not intended for detection of hazardous voltages.

Use personal protective equipment to prevent shock and arc blast injury where hazardous live conductors are exposed.

While using this product, you may need to access other parts of a larger system. Read the safety sections of the other component manuals for warnings and cautions related to operating the system.

When incorporating this equipment into a system, the safety of that system is the responsibility of the assembler of the system.

To avoid fire or personal injury

Use proper power cord.

Use only the power cord specified for this product and certified for the country of use.

Ground the product.

This product is grounded through the grounding conductor of the power cord. To avoid electric shock, the grounding conductor must be connected to earth ground. Before making connections to the input or output terminals of the product, ensure that the product is properly grounded. Do not disable the power cord grounding connection.

Power disconnect.

The power cord disconnects the product from the power source. See instructions for the location. Do not position the equipment so that it is difficult to operate the power cord; it must remain accessible to the user at all times to allow for quick disconnection if needed.

Observe all terminal ratings.

To avoid fire or shock hazard, observe all rating and markings on the product. Consult the product manual for further ratings information before making connections to the product.

Do not apply a potential to any terminal, including the common terminal, that exceeds the maximum rating of that terminal.

Do not operate without covers

Do not operate this product with covers or panels removed, or with the case open. Hazardous voltage exposure is possible.

Avoid exposed circuitry

Do not touch exposed connections and components when power is present.

Do not operate with suspected failures.

If you suspect that there is damage to this product, have it inspected by qualified service personnel.

Disable the product if it is damaged. Do not use the product if it is damaged or operates incorrectly. If in doubt about safety of the product, turn it off and disconnect the power cord. Clearly mark the product to prevent its further operation.

Examine the exterior of the product before you use it. Look for cracks or missing pieces.

Use only specified replacement parts.

Do not operate in wet/damp conditions

Be aware that condensation may occur if a unit is moved from a cold to a warm environment.

Do not operate in an explosive atmosphere

Keep product surfaces clean and dry

Remove the input signals before you clean the product.

Provide proper ventilation.

Refer to the installation instructions in the manual for details on installing the product so it has proper ventilation.

Slots and openings are provided for ventilation and should never be covered or otherwise obstructed. Do not push objects into any of the openings.

Provide a safe working environment

Always place the product in a location convenient for viewing the display and indicators.

Avoid improper or prolonged use of keyboards, pointers, and button pads. Improper or prolonged keyboard or pointer use may result in serious injury.

Be sure your work area meets applicable ergonomic standards. Consult with an ergonomics professional to avoid stress injuries.

Use care when lifting and carrying the product. This product is provided with a handle or handles for lifting and carrying.

WARNING:The product is heavy. To reduce the risk of personal injury or damage to the device get help when lifting or carrying the product.
WARNING:The product is heavy. Use a two-person lift or a mechanical aid.

Use only the Tektronix rackmount hardware specified for this product.

Service safety summary

The Service safety summary section contains additional information required to safely perform service on the product. Only qualified personnel should perform service procedures. Read this Service safety summary and the General safety summary before performing any service procedures.

To avoid electric shock

Do not touch exposed connections.

Do not service alone

Do not perform internal service or adjustments of this product unless another person capable of rendering first aid and resuscitation is present.

Disconnect power

To avoid electric shock, switch off the product power and disconnect the power cord from the mains power before removing any covers or panels, or opening the case for servicing.

Use care when servicing with power on

Dangerous voltages or currents may exist in this product. Disconnect power, remove battery (if applicable), and disconnect test leads before removing protective panels, soldering, or replacing components.

Verify safety after repair

Always recheck ground continuity and mains dielectric strength after performing a repair.

Terms in this manual

These terms may appear in this manual:

WARNING:Warning statements identify conditions or practices that could result in injury or loss of life.
CAUTION:Caution statements identify conditions or practices that could result in damage to this product or other property.

Terms on the product

These terms may appear on the product:

  • DANGER indicates an injury hazard immediately accessible as you read the marking.
  • WARNING indicates an injury hazard not immediately accessible as you read the marking.
  • CAUTION indicates a hazard to property including the product.

Symbols on the product



When this symbol is marked on the product, be sure to consult the manual to find out the nature of the potential hazards and any actions which have to be taken to avoid them. (This symbol may also be used to refer the user to ratings in the manual.)

The following symbols(s) may appear on the product.

Preface

This manual contains specifications and performance verification procedures for the AWG5200 Series Arbitrary Waveform Generators.

Related documents

he following documents are also available for this product and can be downloaded from the Tektronix website www.tek.com/manual/downloads.

  • AWG5200 Series Installation and Safety Manual. This document provides safety information and how to install the generator. Tektronix part number: 071-3529-xx.
  • AWG5200 Series Programmer Manual. This document provides the programming commands to remotely control the generator. Tektronix part number: 077-1337-xx.
  • AWG5200 User Manual. This document is a printable version of the AWG5200 help system. Tektronix part number: 077-1334-xx.

Specifications

This section contains the specifications for the AWG5200 series Arbitrary Waveform Generators.

All specifications are typical unless noted as warranted. Warranted specifications that are marked with the symbol are checked in this manual.

Performance conditions

To meet specifications, the following conditions must be met:

  • The instrument must have been calibrated/adjusted at an ambient temperature between +20 °C and +30 °C.
  • The instrument must be operating within the environmental limits. (See Table 38 on page 26).
  • The instrument must be powered from a source that meets the specifications. (See Table 36 on page 23).
  • The instrument must have been operating continuously for at least 20 minutes within the specified operating temperature range.

Mechanical characteristics

Table 1. Mechanical characteristics
CharacteristicsDescription
Net weight
AWG5202AWG5204AWG5208
Without package44 lb (19.96 kg)45.45 lb (20.62 kg),50.7 lb (23 kg),
With package46.35 lb (21.02 kg)47.75 lb (21.66 kg)53 lb (24.04 kg)
Dimensions, with feet and handles
Height153.6 mm (6.05 in)
Width460.5 mm (18.13 in)
Length603 mm (23.76 in)
Cooling methodForced-air circulation with no air filter.
Cooling clearance
Top0 in
Bottom0 in
Left side50 mm (2 in)
Right side50 mm (2 in)
Rear0 in


Environmental characteristics

Table 1. Environmental characteristics
CharacteristicsDescription
Temperature
Operating0 °C to +50 °C (+32 °F to 122 °F)
Non-operating

–20 °C to +60 °C (-4 °F to 140 °F) with 30 °C/hour (86 °F/hour) maximum gradient, with

no media installed in disc drives.

Relative humidity
Operating

5% to 90% relative humidity at up to +30 °C (+86 °F).

5% to 45% relative humidity above +30 °C (+86 °F) up to +50 °C (122 °F) non-condensing.

Non-operating

5% to 90% relative humidity at up to 30 °C.

5% to 45% relative humidity above +30 °C (+86 °F) up to +60 °C (140 °F) non-condensing.

Altitude
Operating

Up to 3,000 m (approximately 10,000 feet).

Maximum operating temperature decreases 1 °C (34 °F) each 300 m (984 ft) above 1.5 km

(4921 ft).

Non-operatingUp to 12,000 m (approximately 40,000 feet).

Performance verification procedures

Two types of performance verification procedures can be performed on the instrument: Brief Procedures and Performance Tests. You may not need to perform all of these procedures, depending on what you want to accomplish.

  • To rapidly confirm that the instrument functions and was adjusted properly, perform Diagnostics and Calibration.

Advantages: These procedures are quick to do and require no external equipment or signal sources. These procedures perform extensive functional and accuracy testing to provide high confidence that the instrument will perform properly.

  • To further check functionality, first perform Diagnostics and Calibration, and then perform Functional Test.

Advantages: The procedure requires minimal additional time to perform, and requires minimal equipment. The procedure can be used when the instrument is first received.

  • If more extensive confirmation of performance is desired, complete the self tests and functional test, and then do the Performance Tests.

Advantages: These procedures add direct checking of warranted specifications. These procedures require specific test equipment. (See page 44, Required equipment).

If you are not familiar with operating this instrument, refer to the online help or the user information supplied with the instrument.

Input and output options

The instrument has two USB ports on the front panel, and four USB ports on the rear panel. (See Figure 1). These ports can be used for an external mouse and/or keyboard. Additionally, an external video display can be connected to the VGA display port on the rear panel.
Figure 1. Pheripheral connections


Brief procedures

There are three procedures in this section that provide a quick way to confirm basic functionality and proper adjustment:

  • Diagnostics
  • Calibration
  • Functional test

Diagnostics

The following steps run the internal routines that confirm basic functionality and proper adjustment.

EquipmentPrerequisites
NoneNone
  1. Disconnect all the cables from the output channels.
  2. From the Utilities tab, select Diag & Cal.
  3. Click the Diagnostics & Calibration button and then select Diagnostics.

  4. In the Diagnostics dialog box, confirm that all the check boxes are selected. If they are not selected, click the Select all tests button.
  5. Click Start button to execute the diagnostics.

    The internal diagnostics perform an exhaustive verification of proper instrument function. This verification may take several minutes. When the verification is completed, the resulting status will appear in the dialog box.

  6. Verify that Pass appears as Status in the dialog box when the diagnostics complete.
  7. Click the Close button.

Calibration

EquipmentPrerequisites
None Power on the instrument and allow a 20 minute warm-up before doing this procedure.
  1. From the Utilities tab, select System.
  2. From the Utilities tab, select Diag & Cal.
    Click the Diagnostics & Calibration button and then select Calibration.

  3. Click the Start button to start the routine.
  4. Verify that Pass appears in the Summary column for all items when the calibration completes.
  5. Click the Close button.

Functional tests

The purpose of the procedure is to confirm that the instrument functions properly.

The procedures use “AWG” when referring to the AWG5200 series instruments.

The required equipment is listed below.

Table 1. Required equipment for the functional test
ItemQty.Minimum requirementsRecommended equipment
Oscilloscope1 ea.Bandwidth: 4 GHz or higher 4 channelsTektronix DPO70404C
Function generator1 ea.1 kHz, square wave, 5 Vp-p outputTektronix AFG3021C
Signal analyzer1 ea.Bandwidth: 14 GHz or higherTektronix RSA5126B
Adapter4 ea.TekConnect oscilloscope input to SMA inputTektronix TCA-SMA
50 Ω SMA cable4 ea.DC to 20 GHzTensolite 1-3636-465-5236
50 Ω SMA terminator3 ea.DC to 18 GHz

Tektronix part number 136-7162-xx

(supplied with AWG).

50 Ω BNC cable1 ea.Male connectors both endsTektronix part number 012-0057-01
SMA-BNC adapter3 ea.SMA female to BNC male connectorTektronix part number 015-0572-00
Planar Crown RF Input Connector – 7005A-1 SMA Female1 ea.

Planar Crown RF Input Connector – Type N to SMA Female

For use with Tektronix RSA5126B signal analyzer

Tektronix part number 131-8689-00

Functional check prerequisites

  1. Click the Reset to Default Setup button in the toolbar
  2. Load the test waveform PV_Square.wfmx into the Waveform List.

    Test waveforms are located at C:\Program Files\Tektronix\AWG5200\Samples\PV.

Checking the analog channel outputs

Required equipment
OscilloscopeNone
One TCA-SMA adapter
One 50 Ω SMA cable
One 50 Ω SMA terminator
  1. Set the test oscilloscope as follows:
    1. Vertical scale: 200 mV/div (CH 1 and CH 2)
    2. Horizontal scale: 100 ns/div
    3. Input coupling: DC (CH 1 and CH 2)
    4. Input impedance: 50 Ω (CH 1 and CH 2)
    5. Position: +2 div (CH 1 and CH 2, if necessary)
    6. Trigger source: CH 1
    7. Trigger level: 0 mV
    8. Trigger slope: Positive
    9. Trigger slope: Auto
  2. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  3. Connect CH 1 (+) of the AWG to channel 1 of the test oscilloscope using a 50 Ω SMA cable and a TCA-SMA adapter.
  4. Connect CH 1 (–) of the AWG to channel 2 of the test oscilloscope using a 50 Ω SMA cable and a TCA-SMA adapter.

  5. Click the Home tab on the display.
  6. From the Waveform List window, assign the waveform PV_Square.wfmx to Channel 1.
  7. Click the Setup -> Channel tab and enable Channel 1.

  8. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  9. Click the Play button on-screen or press the button on the front panel of the AWG.
  10. Check that the channel’s waveform is properly displayed on the test oscilloscope screen.

  11. Press AWG the front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  12. Repeat steps 3 through 11 until all channels are checked, modifying the instructions with the channel number under test.
  13. Disconnect the test setup.

Checking the marker outputs

Required equipmentPrerequisites
OscilloscopeNone
Four TCA-SMA adapters
Four 50 Ω SMA cables
  1. Set the test oscilloscope as follows:
    1. Vertical scale: 1 V/div (CH 1 through CH 4)
    2. Horizontal scale: 100 ns/div
    3. Input coupling: DC
    4. Input impedance: 50 Ω
    5. CH 1 through CH 4 position: adjust as necessary to display all four traces
    6. Trigger source: CH1
    7. Trigger level: 0 mV
    8. Trigger slope: Positive
    9. Trigger mode: Auto
  2. If needed, press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  3. Connect the AWG’s Channel 1 markers to the test oscilloscope using a 50 Ω SMA cable and a TCA-SMA adapter.
    • Connect marker CH1:1 to channel 1 of the test oscilloscope.
    • Connect marker CH1:2 to channel 2 of the test oscilloscope.
    • Connect marker CH1:3 to channel 3 of the test oscilloscope.
    • Connect marker CH1:4 to channel 4 of the test oscilloscope.
    Note:If a channel’s marker is not connected to the test oscilloscope, it must be terminated with a 50 Ω SMA terminator

  4. Click the Home tab on the display.
  5. From the Waveform List window, assign the waveform PV_Square.wfmx to Channel 1.
  6. Click the Setup -> Channel tab and enable the select Channel 1 output.

  7. In the Setup -> Channel tab, select Output Settings and set the Channel 1 Resolution to 12+4 Mkrs.
  8. Click the Play button on-screen or on the front panel.
  9. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  10. Check that the CH1:1 through CH1:4 waveforms are properly displayed on the test oscilloscope screen.

  11. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  12. Repeat steps 3 through 11 until all channels are checked, modifying the instructions with the channel number under test.

    Disconnect the setup.

Checking the AC output

Required equipmentPrerequisites
Signal analyzerNone
One 50 Ω SMA cable
Planar Crown RF Input Connector – Type N to SMA Female
Two 50 Ω SMA terminators
  1. If needed, press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  2. Create a 1 GHz test waveform from the AWG using the Basic Waveform plug-in.
    1. Click the Waveform Plug-in tab on the display.
    2. Select Basic Waveform from the Waveform Plug-ins drop down list.

    3. Click the Reset Plug-in button.
    4. Set the Function to Sine.
    5. Set the Frequency to 1 GHz.
      Note:Leave all other settings at their default settings.
    6. Click the Compile Settings icon to open the compile settings dialog screen.
    7. In the Name field, change the name to Waveform_1 GHz.
    8. Close the compile settings dialog screen.
    9. Click Compile.
  3. Set the spectrum analyzer as follows:
    1. Press the Preset button to set the analyzer to its default settings.
    2. Display the Spectrum measurement.
    3. Set Center Frequency to 1 GHz.
  4. Use a 50 Ω SMA cable to connect the CH 1 AC connector (+) on the AWG to the RF input of the signal analyzer.

  5. Click the Setup -> Channel tab and click the Output Settings tab.
    1. Select Channel 1.
    2. Set the Output Path to AC Direct.

    3. Enable the Channel 1 output.

  6. Click the Home tab on the display.
  7. In the Waveform List window, assign the Waveform_1 GHz waveform to the Channel 1.
  8. Press the Play button, or click Play on the display.
  9. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  10. Check that the waveform is properly displayed on the signal analyzer screen.
    Figure 1. 1 GHz output waveform


  11. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  12. Repeat steps 4 through 11 until all channels are checked, modifying the instructions with the channel number under test.

    Disconnect the test setup.

Checking the triggered outputs

Required equipmentPrerequisites
OscilloscopeNone
Function Generator (AFG3021C or equivalent)
One TCA-SMA adapter
Two 50 Ω SMA cables
One SMA female to BNC male adapter
  1. Set the oscilloscope as follows:
    1. Vertical scale: 200 mV/div (CH 1)
    2. Horizontal scale: 20 ns/div
    3. Trigger source: CH 1
    4. Trigger level: 100 mV
  2. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  3. Connect a BNC to SMA adapter to the output of the function generator.
  4. Connect an SMA cable between the output of the function generator and the Trigger A input on the rear panel of the AWG.
  5. Connect CH 1 (+) of the AWG to channel 1 of the test oscilloscope using a 50 Ω SMA cable and a TCA-SMA adapter.

  6. Click the Home tab on the display.
  7. Click the Reset to Default Setup button in the toolbar.
  8. Set the Function Generator to output a 1 kHz square wave at 5 Vp-p.
  9. Turn on the output of the Function Generator.
  10. Load the test waveform PV_Square.wfmx into the Waveform List.

    Test waveforms are located at C:\Program Files\Tektronix\AWG5200\Samples\PV.

  11. From the Waveform List window, assign the waveform PV_Square.wfmx to Channel 1.
  12. Click the Home tab and set the AWG’s Channel 1 as follows:
    • Run Mode to Triggered
    • Trigger Input to A
    • Enable the Channel

  13. In the Setup -> Trigger tab, set the External Trigger Level to 1.0 V (A and B). Leave all other settings to their default settings.
  14. Click the Play button on-screen or on the front panel of the AWG.

  15. Click the Home tab and verify that the squarewave output is displayed on the AWG.
  16. Verify that the squarewave output is displayed on the test oscilloscope.

  17. Move the cable from the Trigger A input to the Trigger B input.

  18. Click the Home tab and set the trigger input to B.
  19. Verify that the output is displayed on the test oscilloscope (as in step 17).

  20. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  21. Disconnect the test setup.

Performance tests

This section contains performance verification procedures for the specifications listed below.
  • 10 MHz reference frequency accuracy
  • Analog amplitude accuracy
  • Marker high and low level accuracy

Prerequisites

The tests in this section provide confirmation of performance and functionality.

The following requirements and conditions must be met:
  • The cabinet must be installed.
  • The AWG must have been last adjusted at an ambient temperature between +20 °C and +30 °C, must have been operating for a warm-up period of at least 20 minutes, and must be operating at an ambient temperatures between +10 °C and +40 °C.
  • You must have performed and passed the procedure Diagnostics and Calibration, and the procedure Functional Tests.

Required equipment

The following table lists the test equipment required to perform the performance verification procedures. The table identifies examples of recommended equipment and lists the required precision where applicable. If you substitute other test equipment for the listed examples, the equipment must meet or exceed the listed tolerances.

ItemQty.Minimum requirementsRecommended equipment
Frequency counter1 ea.Frequency accuracy: within ± 0.01 ppmTektronix MCA3040
Digital multimeter1 ea.DC accuracy: within ± 0.01%Keithley 2000 DMM or Tektronix DMM4040/4050
Adapter3 ea.TekConnect oscilloscope input to SMA input Tektronix TCA-SMA
50 Ω SMA cable1 ea.DC to 20 GHzTensolite 1-3636-465-5236
50 Ω SMA terminator3 ea.DC to 18 GHzTektronix part number 136-7162-xx (supplied with AWG).
50 Ω BNC feed-through terminator1 ea.DC to 1 GHz, feedthroughTektronix part number 011-0049-02
Table 1. Required equipment for performance tests
ItemQty. Minimum requirementsRecommended equipment
SMA-BNC adapter3 ea.SMA female to BNC male connectorTektronix part number 015-0572-00
SMA-BNC adapter1 ea.SMA male to BNC female connectorTektronix part number 015-0554-00
BNC-dual banana adapter1 ea.BNC to dual banana plugsTektronix part number 103-0090-00

Test record

Photocopy the test records and use them to record the performance test results. (See page 66, Test record).

Termination resistance measurement

Many of the performance tests use a BNC-dual banana adapter and 50 Ω BNC feed-through terminator connected to a DMM.

For accuracy, the termination resistance of this connection is used in the calculations.

Use this procedure and note the measured value for use in these procedures.

  1. Connect the BNC-dual banana adapter and 50 Ω BNC feed-through terminator to the HI and LO inputs of the digital multimeter.
    Figure 1. Equipment connection to measure terminator resistance


  2. Set the digital multimeter to the Ω 2 wires mode.
  3. Measure the resistance and note the value as Term_R.

    Keep this value available for use in several performance check calculations.

  4. Set the digital multimeter to the DCV mode.
    Note:Lead resistance is not included in the measurement results when using four wire ohms. The accuracy is higher especially for small resistances. Use a four wire method if necessary.

Analog amplitude accuracy

Required equipmentPrerequisites
Digital multimeter

AWG preparation and load test waveforms (See page 44.)

Termination resistance measurement procedure (Term R) (See page 46.)

BNC-dual banana adapter
50 Ω BNC feed-through terminator
SMA female-BNC male adapter
50 Ω SMA terminator

Before starting this procedure, ensure you have the “Term R” value used in the calculations. (See page 46, Termination resistance measurement.)

DC High BW output path

  1. Click the Reset to Default Setup button in the toolbar.
  2. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  3. Load the test waveforms PV_DC_Plus.wfmx and PV_DC_Minus.wfmx into the Waveform List.
    Note:Test waveforms are located at C:\Program Files\Tektronix\AWG5200\Samples\PV.
  4. From the Waveform List window, assign the test waveform PV_DC_Plus.wfmx to Channel 1.
  5. Connect the CH 1 (+) connector from the AWG to the HI and LO inputs of the digital multimeter.

    Use a 50 Ω SMA cable, a BNC-SMA adapter, a 50 Ω BNC feed-through terminator, and a BNC dual banana adapter.

  6. Terminate the CH 1 (–) connector on the AWG with a 50 Ω SMA terminator.

  7. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  8. Click the Setup -> Channel tab and click the Output Settings tab.
    1. Select Channel 1.
    2. Set the Output Path to DC High BW.

    3. Enable the Channel 1 output.

  9. Set the Amplitude of the AWG as shown in the following table. (See Table 41.)
    Table 1. Analog amplitude accuracy (DC High BW output path)
    Amplitude settingsAccuracy limits
    25 mVp-p23.75 mV to 26.25 mV
    100 mVp-p98 mV to 102 mV
    200 mVp-p196 mV to 204 mV
    500 mVp-p480 mV to 520 mV
    1 Vp-p980 mV to 1.02 V
    (Requires option DC)
    1.5 Vp-p1.47 V to 1.53 V
    (Requires option DC)
  10. Press the Play button, or click Play on the display.
  11. Measure the output voltage on the digital multimeter and note the value as Measured_voltage_1.
  12. Use the following formula to compensate the voltage for the 50 Ω BNC feed-through terminator:

    V_high = [(Term_R + 50) / (2 Term_R)] Measured_voltage_1

    Where Term_R is the resistance of the 50 Ω BNC feed-through terminator (See page 46, Termination resistance measurement.) procedure.

  13. From the Waveform List window, assign the waveform PV_DC_Minus.wfmx to Channel 1.
  14. Measure the output voltage on the digital multimeter and note the value as Measured_voltage_2.
  15. Use the following formula to compensate the voltage for the 50 Ω BNC feed-through terminator:

    V_low = [(Term_R + 50) / (2 Term_R)] Measured_voltage_2

    Where Term_R is the resistance of the 50 Ω BNC feed-through terminator (See page 46, Termination resistance measurement.) procedure.

  16. Verify that the voltage difference |(V_high – V_low)| falls within the limits given in the table. (See Table 41 on page 48.)
  17. Repeat steps 9 through 16 for each Amplitude setting in the table. (See Table 41 on page 48.)
  18. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  19. Move the SMA cable from the CH 1 (+) connector to the CH 1 (–) connector and move the 50 Ω SMA terminator from the CH 1 (–) connector to the CH 1 (+) connector.

  20. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  21. Repeat steps 9 through 17 for the CH1 (–) connector.
  22. Repeat steps 4 through 21 until all channels are checked, modifying the instructions for the channel under test.
  23. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  24. Disconnect the test setup.

DC High Volt output path

Note:This is the start of testing the optional DC High Volt output path (Option HV).

If option HV is not licensed, skip this procedure.

  1. Click the Reset to Default Setup button in the toolbar.
  2. Load the test waveforms PV_DC_Plus.wfmx and PV_DC_Minus.wfmx into the Waveform List.
    Note:Test waveforms are located at

    C:\Program Files\Tektronix\AWG5200\Samples\PV.

  3. From the Waveform List window, assign the waveform PV_DC_Plus.wfmx to Channel 1.
  4. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  5. Connect the CH 1 (+) connector from the AWG to the HI and LO inputs of the digital multimeter.

    Use a 50 Ω SMA cable, a BNC-SMA adapter, a 50 Ω BNC feed-through terminator, and a BNC dual banana adapter.

  6. Terminate the CH 1 (–) connector on the AWG with a 50 Ω SMA terminator.

  7. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  8. Click the Setup -> Channel tab and click the Output Settings tab.
    1. Select Channel 1.
    2. Set the Output Path to DC High Volt.

    3. Enable the Channel 1 output.

  9. Set the Amplitude of the AWG as shown in the following table. (See Table 42.)
    Table 2. Analog amplitude accuracy (DC High Volt output path)
    Amplitude settingsAccuracy limits
    10 mVp-p9.5 mV to 10.5 mV
    100 mVp-p98 mV to 102 mV
    500 mVp-p480 mV to 520 mV
    5 V4.92 V to 5.08 V
  10. Press the Play button, or click Play on the display.
  11. Measure the output voltage on the digital multimeter and note the value as Measured_voltage_1.
  12. Use the following formula to compensate the voltage for the 50 Ω BNC feed-through terminator:

    V_high = [(Term_R + 50) / (2 Term_R)] Measured_voltage_1

    Where Term_R is the resistance of the 50 Ω BNC feed-through terminator (See page 46, Termination resistance measurement.) procedure.

  13. From the Waveform List window, assign the waveform PV_DC_Minus.wfmx to Channel 1.
  14. Measure the output voltage on the digital multimeter and note the value as Measured_voltage_2.
  15. Use the following formula to compensate the voltage for the 50 Ω BNC feed-through terminator:

    V_low = [(Term_R + 50) / (2 Term_R)] Measured_voltage_2

    Where Term_R is the resistance of the 50 Ω BNC feed-through terminator (See page 46, Termination resistance measurement.) procedure.

  16. Verify that the voltage difference |(V_high – V_low)| falls within the limits given in the table. (See Table 42 on page 52.)
  17. Repeat steps 9 through 16 for each amplitude setting in the table. (See Table 42 on page 52.)
  18. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  19. Move the SMA cable from the CH 1 (+) connector to the CH 1 (–) connector and move the 50 Ω SMA terminator from the CH 1 (–) connector to the CH 1 (+) connector.

  20. Repeat steps 9 through 17 for the CH1 (–) connector.
  21. Repeat steps 3 through 20 until all channels are checked, modifying the instructions for the channel under test.
  22. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  23. Disconnect the test setup.

Analog offset accuracy (DC output paths)

Required equipmentPrerequisites
Digital multimeterAWG preparation and load test waveforms(See page 44, Prerequisites.)

Termination resistance measurement procedure

BNC-dual banana adapter
50 Ω BNC feed-through terminator
SMA female-BNC male adapter
50 Ω SMA terminator

Before starting this procedure, ensure you have the “Term R” value used in the calculations. (See page 46, Termination resistance measurement.)

  1. Click the Reset to Default Setup button in the toolbar.

    Note:Test assumes Reset to Default sets the Amplitude to 500 mVpp.
  2. Load the test waveform PV_DC_Zero.wfmx into the Waveform List.
    Note:Test waveforms are located at C:\Program Files\Tektronix\AWG5200\Samples\PV.
  3. From the Waveform List window, assign the waveform PV_DC_Zero.wfmx to Channel 1.
  4. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  5. Connect the CH 1 (+) connector from the AWG to the HI and LO inputs of the digital multimeter. Use a 50 Ω SMA cable, a BNC-SMA adapter, a 50 Ω BNC feed-through terminator, and a BNC dual banana adapter.
  6. Terminate the CH 1 (–) connector on the AWG using a 50 Ω SMA terminator.

  7. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  8. Click the Setup -> Channel tab and click the Output Settings tab.
    1. Select Channel 1.
    2. Set the Output Path to DC High BW.

    3. Enable the Channel 1 output.

  9. Set the Offset of the AWG as shown in the first row of the following table. (See Table 43.)
    Table 1. Offset accuracy
    Offset settingsAccuracy limits
    2 V 1.95 V to 2.05 V
    0 V–10 mV to 10 mV
    -2 V-2.05 V to –1.95 V
  10. Press the Play button, or click Play on the display.
  11. Measure the output voltage on the digital multimeter and note the value as Measured_voltage.
  12. Use the following formula to compensate the voltage for the 50 Ω BNC feed-through terminator:

    V = [(Term_R + 50) / (2×Term_R)] × Measured_voltage

    Where Term_R is the resistance of the 50 Ω BNC feed-through terminator (See page 46, Termination resistance measurement.) procedure.

  13. Verify that the voltage V falls within the limits given in the table. (See Table 43 on page 55.)
  14. Repeat steps 9 through 13 for each offset setting in the table. (See Table 43 on page 55.)
  15. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  16. Move the SMA cable from the CH 1 (+) connector to the CH 1 (–) connector and move the 50 Ω SMA terminator from the CH 1 (–) connector to the CH 1 (+) connector.

  17. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  18. Repeat steps 9 through 14 for the (–) output.
  19. Repeat steps 3 through 18 until all channels are checked, modifying the instructions for the channel under test.
    Note:This is the start of testing the optional DC High Volt output path.

    If option HV is licensed, continue with this procedure. If not, skip to step 22.

  20. Click the Setup -> Channel tab and click the Output Settings tab.
    1. Select Channel 1.
    2. Set the Output Path to DC High Volt.

    3. Enable the Channel 1 output.

  21. Repeat steps 9 through 19 for the DC High Volt path.
  22. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  23. Disconnect the test setup.

Analog output DC Bias accuracy (AC output paths)

Required equipmentPrerequisites
Digital multimeterAWG preparation and load test waveforms(See page 44, Prerequisites).

Termination resistance measurement procedure

BNC-dual banana adapter
50 Ω BNC feed-through terminator
SMA female-BNC male adapter
50 Ω SMA terminator

Before starting this procedure, ensure you have the “Term R” value used in the calculations. (See page 46, Termination resistance measurement.)

  1. Click the Reset to Default Setup button in the toolbar.
  2. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  3. Connect the CH 1 (+) connector from the AWG to the HI and LO inputs of the digital multimeter. Use a 50 Ω SMA cable, a BNC-SMA adapter, and a BNC dual banana adapter.
  4. Terminate the CH 1 (–) connector on the AWG using a 50 Ω SMA terminator.

  5. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to enable the outputs (front panel light off).
  6. Click the Setup -> Channel tab and click the Output Settings tab.
    1. Select channel 1.
    2. Set the Output Path to AC Direct.

    3. Enable the Channel 1 output.

  7. Set the DC Bias of the AWG as shown in the first row of the following table. (See Table 44.)
    Table 1. Analog DC bias accuracy
    Bias settingsAccuracy limits
    5 V4.88 V to 5.12 V
    0 V–20 mV to 20 mV
    -5 V–5.12 V to –4.88 V
  8. Measure the output voltage on the digital multimeter and note the value as V_1.
  9. Press the front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  10. Measure the output voltage on the digital multimeter and note the value as V_2 (DMM residual voltage).
  11. Verify that the voltage difference (V_1 – V_2) falls within the limits given in the table. (See Table 44 on page 58.)
  12. Repeat steps 7 through 11 for each bias setting in the table. (See Table 44 on page 58.)
  13. Repeat steps 3 through 12 until all channels are checked, modifying the instructions for the channel number under test.
    Note:This is the start of testing the optional AC Amplified output path.

    If option AC is licensed, continue with this procedure. If not, skip to step 17.

  14. Click the Setup -> Channel tab and click the Output Settings tab.
    1. Select Channel 1.
    2. Set the Output Path to AC Amplified.

  15. Repeat steps 7 through 13 until all channels are checked, modifying the instructions for the channel number under test.
  16. Press the AWG front panel All Outputs Off button (or click All Outputs Off on the Home screen) to disable the outputs (front panel light on).
  17. Disconnect the test setup.

10 MHz reference frequency accuracy

Required equipment Prerequisites
Frequency counter(See page 44, Prerequisites).
SMA female-to-BNC male adapter
50 Ω SMA cable
  1. Click the Reset to Default Setup button in the toolbar.
  2. Connect the 10 MHz Reference Output on the rear of the AWG to the input of the Frequency Counter. Use a 50 Ω SMA cable and a BNC-SMA adapter.

  3. On the Frequency Counter, press the Meas and the Freq buttons.
  4. Verify that the frequency counter reading falls within the range of 9.99998 MHz to 10.00002 MHz.
  5. Disconnect the test setup.

Test record

Photocopy the test record pages and use them to record the performance test results for your AWG.

AWG5200 series performance test record

AWG Model:
AWG Serial Number:Certificate Number:
Temperature:RH %:
Date of Calibration:Technician:
Performance testMinimum Test resultMaximum

Analog Amplitude Accuracy

DC High BW Output Path

AWG5202, AWG5204, AWG5208
Ch 1 +Amplitude
25 mVP-P23.75 mV26.25 mV
100 mVP-P98 mV102 mV
200 mVP-P196 mV204 mV
500 mVP-P480 mV520 mV
1 VP-P980 mV1.02 V
1.5 VP-P1.47 V1.53 V
Ch 2 +Amplitude
25 mVP-P23.75 mV26.25 mV
100 mVP-P98 mV102 mV
200 mVP-P196 mV204 mV
500 mVP-P480 mV520 mV
1 VP-P980 mV1.02 V
1.5 VP-P1.47 V1.53 V
AWG5204, AWG5208
Ch 3 +Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch 4 +Amplitude
25 mVp-p23.75 mV26.25 mV
100 mVp-p98 mV102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
AWG5208
Ch 5 +Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch 6 +Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch 7+Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch8+Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
AWG5202, AWG5204, AWG5208
Ch 1 –Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch 2 –Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
AWG5204, AWG5208
Ch 3 –Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch 4 –Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
AWG5208
Ch 5 –Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch 6 –Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch 7–Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V
Ch 8 –Amplitude
25 mVp-p23.75 mV 26.25 mV
100 mVp-p98 mV 102 mV
200 mVp-p196 mV204 mV
500 mVp-p480 mV520 mV
1 Vp-p980 mV1.02 V
1.5 Vp-p1.47 V 1.53 V

Analog Amplitude Accuracy

High Volt Output Path

AWG5202, AWG5204, AWG5208
Ch 1 +Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 2 +Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
AWG5204, AWG5208
Ch 3 +Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 4 +Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
AWG5208
Ch 5 +Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 6 +Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 7 +Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 8 +Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
AWG5202, AWG5204, AWG5208
Ch 1 –Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 2 –Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
AWG5204, AWG5208
Ch 3 –Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 4 –Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
AWG5208
Ch 5 –Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 6 –Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 7 –Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V
Ch 8 –Amplitude
10 mVp-p9.5 mV10.5 mV
100 mVp-p98 mV102 mV
500 mVp-p480 mV 520 mV
5 Vp-p4.92 V 5.08 V

Analog Offset Accuracy

(DC High BW Output Path)

AWG5202, AWG5204, AWG5208

Ch 1 +Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 2 +Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
AWG5204, AWG5208
Ch 3 +Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 4 +Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
AWG5208
Ch 5 +Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 6 +Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 7 +Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 8 +Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
AWG5202, AWG5204, AWG5208
Ch 1 –Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 2 –Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
AWG5204, AWG5208
Ch 3 –Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 4 –Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
AWG5208
Ch 5 –Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 6 –Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 7 –Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V
Ch 8 –Offset
2 V1.95 V2.05 V
0 V–10 mV10 mV
-2 V–2.05 V–1.95 V

Analog Offset Accuracy

(DC High Volt Output Path)

AWG5202, AWG5204, AWG5208

Ch 1 +OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 V–1.935 V
Ch 2 +OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 V–1.935 V
AWG5204, AWG5208
Ch 3 +OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 V–1.935 V
Ch 4 +OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
AWG5208
Ch 5 +OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
Ch 6 +OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
Ch 7 +OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
Ch 8 +OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
AWG5202, AWG5204, AWG5208
Ch 1 – OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
Ch 2 – OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
AWG5204, AWG5208
Ch 3 –OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
Ch 4 –OffsetAmplitude
2 V500 mVpp1.9352.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
AWG5208
Ch 5 –OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
Ch 6 –OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
Ch 7 –OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V
Ch 8 –OffsetAmplitude
2 V500 mVpp1.935 V2.065 V
0 V500 mVpp–25 mV25 mV
-2 V500 mVpp–2.065 mV–1.935 V

Analog DC Bias Accuracy

(AC Direct Output Path)

AWG5202, AWG5204, AWG5208
Ch 1 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 2 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5204, AWG5208
Ch 3 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 4 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5208
Ch 5 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 6 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 7 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 8 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5202, AWG5204, AWG5208
Ch 1 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 2 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5204, AWG5208
Ch 3 – DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 4 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5208
Ch 5 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 6 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 7 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 8 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V

Analog DC Bias Accuracy

(AC Amplified Output Path)

AWG5202, AWG5204, AWG5208

Ch 1 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 2 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5204, AWG5208
Ch 3 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 4 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5208
Ch 5 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 6 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 7 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 8 +DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5202, AWG5204, AWG5208
Ch 1 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 2 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5204, AWG5208
Ch 3 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 4 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
AWG5208
Ch 5 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 6 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 7 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V
Ch 8 –DC Bias
5 V 4.88 V5.12 V
0 V–20 mV 20 mV
–5 V–5.12 V–4.88 V

Marker

High Level Accuracy

AWG5202, AWG5204, AWG5208

CH1:1+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH1:2+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH1:3+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH1:4+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH2:1+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH2:2+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH2:3+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH2:4+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
AWG5204, AWG5208
CH3:1+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH3:2+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH3:3+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH3:4+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH4:1+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH4:2+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH4:3+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH4:4+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
AWG5208
CH5:1+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH5:2+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH5:3+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH5:4+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH6:1+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH6:2+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH6:3+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH6:4+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH7:1+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH7:2+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH7:3+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH7:4+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH8:1+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH8:2+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH8:3+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V
CH8:4+ 1.75 V1.55 V1.95 V
0.0 V–25 mV+25 mV
–0.3 V–0.305 V–0.295 V

Marker

Low Level Accuracy

AWG5202, AWG5204, AWG5208
CH1:1+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH1:2+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH1:3+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH1:4+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH2:1+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH2:2+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH2:3+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH2:4+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
AWG5204, AWG5208
CH3:1+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH3:2+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH3:3+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH3:4+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH4:1+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH4:2+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH4:3+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH4:4+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
AWG5208
CH5:1+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH5:2+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH5:3+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH5:4+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH6:1+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH6:2+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH6:3+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH6:4+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH7:1+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH7:2+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH7:3+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH7:4+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH8:1+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH8:2+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH8:3+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
CH8:4+ 1.55 V1.37 V1.73 V
0.0 V–25 mV 25 mV
–500 mV–0.525 V-0.475 V
10 MHz Reference Frequency Accuracy
9.99998 MHz10.00002 MHz

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