M9336A-M02_技术文档

Keysight Technologies

M9336A PXIe I/Q Arbitrary Waveform

Generator

540 MHz bandwidth, 16-bit, 3 scalar channels

Data Sheet

Exceptional performance in a single-slot PXIe module

The Keysight Technologies, Inc. M9336A PXIe Arbitrary Waveform Generator (AWG)

provides multiple independent or synchronized signal outputs with exceptional perfor-

mance in a single-slot PXIe module. It is ideal for creating digitally modulated waveforms

for wideband communication systems and high resolution waveforms for radar and satellite

test. Industry standard waveforms for the AWG can be easily generated using Keysight

software applications tools such as Signal Studio or Waveform Creator. In addition to these

tools, users can generate their own waveforms using MATLAB or custom tools. The AWG

provides standard IVI compliant drivers for integration with multiple application develop-

ment environments.

Applications

– Generation of wide-bandwidth baseband I/Q communication signals with synchronized

envelope tracking signals

– High bandwidth, small sample size control signals used for quantum computing

– DOCSIS upstream signals

– Satellite and radar signals

– General purpose, multi-channel arbitrary waveform generation

Key Features

– Single PXIe slot

– 3 differential or single-ended signal channels with SMB connectors

– 16-bit amplitude resolution

– Up to 540 MHz bandwidth per channel (1080 MHz I/Q modulation bandwidth)

– Per channel control of channel skew, gain, and offset

– Highly flexible waveform definition and sequencing with up to 4 GB of waveform sample

and waveform sequencing memory

– Up to 8 marker signals per channel

– Front panel and PXIe backplane triggers and markers

– Keysight exclusive Trueform waveform generation

– Simple to use soft front panel

03 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

M9336A PXIe I/Q Arbitrary Waveform Generator

The M9336A AWG delivers exceptional performance for creation of complex wideband

waveforms. Multiple, 540 MHz bandwidth channels with 16-bit resolution and up to a

1.28 GSa/s sampling rate are provided in a single-slot PXIe instrument. This enables

the AWG to generate wide bandwidth signals with low Error Vector Magnitude (EVM),

making it ideal for creating baseband waveforms for wireless communications, radar, and

satellite. The AWG can also be combined with a wideband I/Q upconverter/modulator,

resulting in modulation bandwidths of 1 GHz at RF frequencies for signal simulations

employed in functional testing of chip sets designed for modern digital communications

radios.

The AWG includes advanced sequencing and triggering modes which can be used to

create complex waveforms and event-based signal simulations. In addition to the driver

API provided with the instrument, the AWG provides a comprehensive soft front panel

(SFP) which speeds test development and debug by enabling the user to interactively

control the module.

Figure 1. M9336A AWG block diagram.

04 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

2) and individual channels can be adjusted with a resolution of

.001 ps. When used in I/Q applications, the channel-to-channel

delay can be used to compensate for modulator behavior which

can improve channel matching resulting in a better EVM of the

test signal. In addition, the third synchronized channel can be

used as a very accurate marker output or as a third signal such as

a synchronized envelope tracking signal.

Exceptional signal quality

The M9336A AWG provides exceptional signal quality which is

essential for reliable and repeatable measurements on today’s

advanced wireless designs. With 16-bit resolution, it generates

full bandwidth SFDR (without harmonics) of >67 dBc on

differential channels. Selectable amplitude flatness correction

can be used to achieve a DC to 540 MHz flatness of ±0.15 dB.

Corrected phase flatness is ±1 degree, also from DC to 540 MHz.

This results in an EVM as low as 75 m% RMS (20 MHz bandwidth

LTE-A signal).

Channel ﬁltering and gain

The AWG has the capability to provide real-time correction

filtering on each of the three analog output channels. This

filter provides a flatter frequency response for each channel

over the entire channel bandwidth. The user can bypass this

filtering, if required. In addition to the digital correction filter,

the instrument provides a high performance reconstruction filter

on each channel that is tuned to the DAC sample rate. For the

real-time correction filter, the AWG uses a unique technique

to match the filter response to the user defined sample rate in

order to maximize the available signal level for the specific signal

bandwidth required. Each channel can be adjusted individually

using the digital or analog gain controls. This is required in

applications where each channel needs to be adjusted to meet

the test system’s requirements. Channel 3 also has an additional

analog amplifier for higher signal levels than channel 1 and 2. This

is provided for envelope tracking standards.

Individual channel capability

The AWG provides three scalar channels with SMB connections

and up to 540 MHz bandwidth. Each channel utilizes a high-res-

olution DAC and can drive both single-ended and balanced

designs. The I/Q channels (channels 1 and 2) are not amplified

and provide an output range of up to 2 Vp-p for differential

signals (1 Vp-p for single-ended). Common mode offsets ranging

from -0.3 to +0.8 V can be added to each channel. The third

channel does include an amplifier and its output range is 3.4 Vp-p

for differential signals (1.7 Vp-p for single-ended) with a common

mode offsets of ±1.2 V. All single-ended channels have a nominal

output impedance of 50 ohms (100 ohms differential).

Each channel has its own waveform sequencer and can operate

independently. The channels can also be synchronized with a

typical channel-to-channel alignment of <20 ps (channels 1 and

Figure 2. Generate complex, wide bandwidth signals with exceptional EVM performance.

05 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Waveform Sequencing

The AWG utilizes a very flexible and powerful waveform sequencer to play simple or

complex waveforms which can be built from several common waveform segments.

Each output channel has its own independent sequencer. Channel sequencers can be

synchronized as required to create tightly aligned channels required for I/Q baseband

signals.

The waveform sequencer gives the user the ability to create long, complex waveforms

while using minimal sample memory. The sequencer operates as follows (see figure 3):

– Each waveform segment is composed of waveform samples.

– Waveform sequences are built by combining waveform segments.

– Segments and sequences can also be combined as needed to create desired

signals.

– Repeat loops can be used to repeat individual segments or the entire waveform

sequence itself. These repeat loops can be nested up to 8 deep.

– The sample rate for the waveform samples is based on the channel sample rate

setting which can be different for each channel.

– Both hardware and software triggers can be used to control how to advance from

one waveform segment to the next within a sequence.

Figure 3. M9336A AWG waveform sequencing

06 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Module memory

The AWG has up to 4 GB of memory which is managed as a single shared storage

space for waveforms, markers, and sequencer programs. The memory segments for the

data that shares this storage space are dynamically allocated. This generally results in

>500 MSa of waveform storage (depending on memory option).

Triggers and markers

The AWG can accept hardware or software triggers which are primarily used to:

– Control the starting of waveform segments/sequences

– Control internal operation of waveform sequences, e.g. loop until trigger and wait for

trigger

Triggers sources include the front panel Ext 1/2 connectors and PXI backplane. Software

triggers are also allowed.

Output markers are used to identify points in time that are correlated to a waveform as it

is played. Each marker is typically aligned with a particular sample of the waveform. The

marker can be output on:

– An analog channel. A marker being output on an analog channel goes through the

same DSP signal chain as other channels and results in the most accurate place-

ment relative to another analog channel.

– Through the front panel Ext 1/2 connectors

– Through the PXI trigger lines

Keysight Trueform signal generation

The AWG includes Keysight’s exclusive Trueform technology that allows waveforms to

be expressed with the same shape, regardless if the signal is 1 Sa/s or the maximum

rate of 1.28 GSa/s. Waveforms are always anti-aliased for exceptional accuracy, and can

be played at the selectable sample rate, without the chance of missing short-duration

anomalies that are critical for testing device reliability. Digital waveforms with transients

and pulses can be reproduced with the same characteristics every time.

Many arbitrary waveform generators store points in memory and then read those points

out one after another and clock them into a DAC. This requires a low-noise variable-fre-

quency clock which adds to complexity and cost. Trueform technology instead uses a

patented virtual variable clock with advanced filtering techniques that track the sample

rate of the arbitrary waveform. This exclusive digital sampling technique results in overall

better signal integrity with more efficient memory use. It also enables the waveform

segment to be scaled in time to produce different frequency shifted versions of the same

waveform simply by changing the waveform sample rate.

07 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

M9336A AWG Software Toolset

Soft front panel interface

An easy-to-use soft front panel (SFP) in-

terface for the AWG is a standard interface

provided with the product (Figure 4). The

SFP can be used to control the AWG and

has the following functions:

– Provide an interactive soft front panel

to allow the user to quickly learn how

to use the instrument

– Configure individual channel physical

connections: differential, single-ended

– Load waveform files

– Develop simple or complex waveform

sequences created using waveform

files

– Control the operation of the module

and how to execute the waveforms:

continuous, burst, immediate or

triggered using software or hardware

inputs, sample rate, synchronous or

independent channel operation.

– Configure channel trigger and marker

source and destination

Figure 4. M9336A AWG soft front panel

Waveform development

There are different ways to develop waveforms for the M9336A AWG:

– M9099A Waveform Creator: supported via a .csv file

– MATLAB and Keysight IQtools Software: the AWG supports .NET driver access or

through a .csv file format.

– SystemVue: the data for the waveform segment created by SystemVue can be

exported to a .csv file compatible with the AWG

– File import: import a .csv or .bin (N5110) file

– Monitor driver calls as the AWG is

controlled via the SFP to allow the

user to quickly integrate API calls into

the test development environment

– Provides module utilities such as

self-test and firmware upgrade

– Signal Studio: uses a waveform license that enables the M9336A to accept the

downloading of Signal Studio waveforms (.wfm format). The license supports four

M9336A modules. Order the M9950A to support up to eight M9336A modules.

IVI drivers

The following Signal Studio products are supported:

– N7600B W-CDMA/HSPA+

– N7601B CDMA2000^®/1xEV-DO

– N7602B GSM/Edge/Evo

– N7608C Custom modulation

– N7612B TD-SCDMA/HSPA

– N7617B WLAN 802.11a/b/g/j/p/n/ac/ah/ax

– N7624B LTE/LTE-Advanced FDD

– N7625B LTE/LTE-Advanced TDD

– N7630C Pre-5G

The AWG provides IVI.NET, IVI-C,

and LabVIEW drivers to enable easy

integration into common test development

environments. These drivers are used with

IDE and test development tools such as

Command Expert, LabVIEW, MATLAB, and

Visual Studio.

– N7650B Signal Studio Waveform Licenses

08 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

Definitions and Conditions

Speciﬁcation

Warranted performance. Speciﬁcations include guardbands to account for the expected statistical performance distribution, measurement uncertainties,

and changes in performance due to environmental conditions. All speciﬁcations apply over the operating environment outlined in “Environmental and

Regulatory” sections of this data sheet. In addition, the following conditions must be met:

– Instrument is within its calibration cycle if calibration is required.

– Instrument has been stored for a minimum of 1 hour within the operating temperature range prior to turn-on and after a 30 minute warm-up period.

- Open a driver session to intialize the power supplies. This can be donen programatically or by opening SFP and connecting to the instruument

Characteristic

A performance parameter that the product is expected to meet before it leaves the factory, but that is not veriﬁed in the ﬁeld and is not covered by the

product warranty. A characteristic includes the same guardbands as a speciﬁcation.

Typical

Expected performance of an average unit when operated over a 20 to 30 °C temperature range. Typical performance is not warranted. The instrument

must be within its calibration cycle if calibration is required.

Nominal

Nominal describes representative performance that is useful in the application of the product when operated over a 20 to 30 °C temperature range.

Nominal performance is not warranted.

Additional Information

All data are measured from multiple units at room temperature and are representative of product performance within the operating temperature range

unless otherwise noted.

The speciﬁcations contained in this document are subject to change.

09 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

General Characteristics

Module characteristics

Bus interface and compatibility

Number of slots

PXIe peripheral module (x8 Gen 2)

1

Module memory (option dependent)

Supported waveform ﬁle formats

Front panel connectors

Ext1 and Ext2

2 or 4 GB

M9336A binary format (.bin), CSV, Signal Studio (.wfm), and N5110 (.bin)

SMB male

Channel 1+ and 1-

Channel 2+ and 2-

Channel 3+ and 3-

Ext Clk In

SMB male

Reserved for future use

Sync

Aux port

Mechanical

Size

3U/1-slot PXIe standard

130.1 x 21.7 x 210 mm; includes connectors and handle extensions

Weight

544 g (1.2 lbs)

DC Power Requirements

DC supply

DC supply current:

+3.3V

Typical

Maximum

2.7 A

3.3 A

48 W

3.0 A

3.8 A

54 W

+12V

Power dissipation

Channel Characteristics

Characteristic

Value

3

Comments

Number of channels

Resolution

Option dependent

16-bit

540 MHz

1080 MHz

DC

Maximum channel bandwidth

Maximum modulation (I/Q) bandwidth

Output coupling

Option dependent

Ch-ch alignment

Between channels 1 and 2

Between channels 3 and other channels

Channel delay

< 20 ps

< 40 ps

Delay range

±0.5*(sample period) or ±1.6 µs whichever is greater Sample period = 1/sample rate

Delay resolution

0.1 ps for sample rates ≥ 2.5 KSa/s

250 ps @ 1 Sa/s

Delay resolution varies with sample rate below

2.5 KSa/s

10 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

Analog Outputs

Characteristic ¹

Amplitude resolution

16-bit

Amplitude DC accuracy

±0.5% of setting ±5 mV

Jitter ⁵

Fc = 10 MHz

Fc ≥ 50 MHz

<1 ps rms

<0.25 ps rms

Rise/fall time (10% to 90%)

Without corrections

With corrections

<1.2 ns, typical

<900 ps, typical

Single-ended output characteristics ¹

Characteristic

Channels 1 & 2

Channel 3

Nominal output impedance

Nominal amplitude range ^{2, 4}

Without corrections

With corrections ³

Offset

50 ohm

0 Vpp to 1 Vpp

0 Vpp to 0.8 Vpp

0 Vpp to 1.65 Vpp

0 Vpp to 1.26 Vpp

Range

-0.3 to +0.81 V

100 uV

±1.2 V

Adjustment resolution

Analog gain

100 uV

Range

15 dB (min=0.11, max=0.66)

0.0001

15 dB (min=0.18, max=1.08)

0.0001

Adjustment resolution

Digital gain

Range

min=0, max=1

0.0001

min=0, max=1

0.0001

Adjustment resolution

1. Each output terminated with 50 ohms to ground.

2. With maximum analog and default digital gain settings. Higher levels of digital gain are possible depending on signal type. For example, channels 1 and 2

can output a with a 1.3 Vpp sinewave. Using maximum digital gain on complex waveforms with high crest factors may cause signal overload.

3. At maximum sample rate. Reducing sample rate will allow for higher amplitude settings.

4. For channel 3, it is recommended to keep (Vpp X Frequency) <2.5x10⁸and offsets = 0V to minimize harmonic distortion. If offsets are used, it is recommend-

ed to keep (Vp X Frequency) <4x10⁷

5. 1 kHz to 10 MHz integration bandwidth

11 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

Analog Outputs (cont’d)

Differential output characteristics ¹

Characteristic

Channels 1 & 2

Channel 3

Nominal output impedance

Nominal amplitude range ^{2, 4}

Without corrections

With corrections ³

Differential offset

Range

100 ohm

0 Vpp to 2 Vpp

0 Vpp to 3.6 Vpp

0 Vpp to 2.5 Vpp

0 Vpp to 1.6 Vpp

±0.35 V

100 uV

±2.40 V

100 uV

Adjustment resolution

Common mode offset

Range

-0.3 to +0.81 V

100 uV

±1.20 V

100 uV

Adjustment resolution

Analog gain

Range

15 dB (min=0.22, max=1.32)

0.0001

15 dB (min=0.36, max=2.1)

0.0001

Adjustment resolution

Digital gain

Range

min=0, max=1

0.0001

min=0, max=1

0.0001

Adjustment resolution

1. Each output terminated with 50 ohms to ground.

2. With maximum analog and default digital gain settings. Higher levels of digital gain are possible depending on signal type. For example, channels 1 and 2

can output a with a 1.3 Vpp sinewave. Using maximum digital gain on complex waveforms with high crest factors may cause signal overload.

3. At maximum sample rate. Reducing sample rate will allow for higher amplitude settings.

4. For channel 3, it is recommended to keep (Vpp X Frequency) <2.5x10⁸and offsets = 0V to minimize harmonic distortion. If offsets are used, it is recommend-

ed to keep (Vp X Frequency) <4x10⁷

12 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

Analog Outputs (cont’d)

Output Frequency Response

Ch 1 and Ch 2 corrected amplitude ﬂatness

±0.1 dB DC - 400 MHz

±0.15 dB >400MHz - 540 MHz

Corrected phase ﬂatness

Analog reconstruction ﬁlter

±1 degree DC - 540 MHz

540 MHz, 9th order elliptical, low pass

Figure 5. Nominal frequency response plot: nominal freq response, channel 1-3

13 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Spectral Characteristics (Channels 1 and 2) - Typical

Characteristic

Single-ended

Differential

Comments

Harmonic distortion

Fc ≤ 200 MHz: 1 Vpp, 0.5 Voff (SE) or 2 Vpp, 0.8 Vcm (Diff)

Fc ≤ 200 MHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

Fc ≤ 200 MHz: 0.5 Vpp, 0 Voff (SE) or 1 Vpp, 0 Vcm (Diff)

Fc ≤ 50 MHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

SFDR without harmonics

≤ -44 dBc

≤ -52 dBc

≤ -54 dBc

≤ -58 dBc

≤ -47 dBc

≤ -64 dBc

≤ -69 dBc

Fc = 500 MHz: 0.8 Vpp, 0 Voff (SE) or 1.6 Vpp, 0 Vcm (Diff)

Fc = 200 MHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

Fc = 50 MHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

SFDR with harmonics

≥ 37 dBc

≥ 58 dBc

≥ 52 dBc

≥ 58 dBc

≥ 67 dBc

Measured DC to 540 MHz

Measured DC to 135 MHz

Fc ≤ 200 MHz: 1 Vpp, 0.5 Voff (SE) or 2 Vpp, 0.8 Vcm (Diff)

Fc ≤ 200 MHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

Fc ≤ 200 MHz: 0.5 Vpp, 0 Voff (SE) or 1 Vpp, 0 Vcm (Diff)

Fc ≤ 50 MHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

Intermod distortion (IMD₃)

≥ 44 dBc

≥ 52 dBc

≥ 53 dBc

≥ 57 dBc

≥ 47 dBc

≥ 63 dBc

≥ 67 dBc

Measured DC to 540 MHz

Measured DC to 135 MHz

Fc = 100 MHz ± 500 KHz: 1 Vpp, 0.5 Voff (SE) or 2 Vpp, 0.8 Vcm (Diff)

Fc = 100 MHz ± 500 KHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

Fc = 10 MHz ± 500 KHz: 1 Vpp, 0.5 Voff (SE) or 2 Vpp, 0.8 Vcm (Diff)

Fc = 10 MHz ± 500 KHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

Third order intercept (TOI)

< -71 dBc

< -73 dBc

< -87 dBc

< -83 dBc

< -60 dBc

< -75 dBc

< -73 dBc

< -85 dBc

Fc = 100 MHz ± 500 KHz: 1 Vpp, 0.5 Voff (SE) or 2 Vpp, 0.8 Vcm (Diff)

Fc = 100 MHz ± 500 KHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

Fc = 10 MHz ± 500 KHz: 1 Vpp, 0.5 Voff (SE) or 2 Vpp, 0.8 Vcm (Diff)

Fc = 10 MHz ± 500 KHz: 1 Vpp, 0 Voff (SE) or 2 Vpp, 0 Vcm (Diff)

Output phase noise (100 MHz output)

> 34 dBm

> 35 dBm

> 43 dBm

> 41 dBm

> 28 dBm

> 36 dBm

> 35 dBm

> 41 dBm

1 kHz offset

10 kHz offset

100 kHz offset

1 Mhz offset

-130 dBc/Hz

-135 dBc/Hz

-137 dBc/Hz

-152 dBc/Hz

-162 dBc/Hz

≤ -159 dBm/Hz

-130 dBc/Hz

-135 dBc/Hz

-137 dBc/Hz

-152 dBc/Hz

-162 dBc/Hz

≤ -159 dBm/Hz

10 Mhz offset

Noise ﬂoor

100 MHz tone, spot noise

measured at 133 MHz

Figure 6. Typical Channel 1-2, 10 MHz tone spectrum

Figure 7. Typical Channel 1-2, 500 MHz tone spectrum

14 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Spectral Characteristics (Chan 1 and 2) (cont'd)

Figure 8. Typical 2nd harmonic distortion, channel 1 and 2, single-ended

Figure 9. Typical 3rd harmonic distortion, channel 1 and 2, single-ended

15 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

Spectral Characteristics (Chan 1 and 2) (cont’d)

Figure 10. Typical 2nd harmonic distortion, channel 1 and 2, differential

Figure 11. Typical 3rd harmonic distortion, channel 1 and 2, differential

16 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Spectral Characteristics (Chan 1 and 2) (cont'd)

Figure 12. Typical Channel 1-2, 100 MHz two tone intermod

Figure 13. Typical Channel 1-2 noise floor

Figure 14. Typical phase noise, channel 1 and 2

17 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Spectral Characteristics (Channel 3) - Typical

Characteristic

Single-ended

Differential

Comments

Harmonic distortion

Fc ≤ 200 MHz: 0.5 Vpp, 0.5 Voff (SE) or 1.0 Vpp, 0.5 Vcm (Diff)

Fc ≤ 200 MHz: 1.0 Vpp, 0 Voff (SE) or 2.0 Vpp, 0 Vcm (Diff)

Fc ≤ 200 MHz: 0.5 Vpp, 0 Voff (SE) or 1.0 Vpp, 0 Vcm (Diff)

Fc ≤ 50 MHz: 1.5 Vpp, 0 Voff (SE) or 3.0 Vpp, 0 Vcm (Diff)

SFDR without harmonics

≤ -31 dBc

≤ -41 dBc

≤ -48 dBc

≤ -64 dBc

≤ -38 dBc

≤ -47 dBc

≤ -60 dBc

≤ -64 dBc

Fc = 500 MHz: 0.25 Vpp, 0 Voff (SE) or 0.5 Vpp, 0 Vcm (Diff)

Fc = 200 MHz: 0.5 Vpp, 0 Voff (SE) or 1.0 Vpp, 0 Vcm (Diff)

Fc = 50 MHz: 1.5 Vpp, 0 Voff (SE) or 3.0 Vpp, 0 Vcm (\Diff)

SFDR with harmonics

≥ 54 dBc

≥ 66 dBc

≥ 64 dBc

≥ 54 dBc

≥ 71 dBc

≥ 69 dBc

Measured DC to 540 MHz

Measured DC to 135 MHz

Fc ≤ 200 MHz: 0.5 Vpp, 0.5 Voff (SE) or 1.0 Vpp, 0.5 Vcm (Diff)

Fc ≤ 200 MHz: 1.0 Vpp, 0 Voff (SE) or 2.0 Vpp, 0 Vcm (Diff)

Fc ≤ 200 MHz: 0.5 Vpp, 0 Voff (SE) or 1.0 Vpp, 0 Vcm (Diff)

Fc ≤ 50 MHz: 1.5 Vpp, 0 Voff (SE) or 3.0 Vpp, 0 Vcm (Diff)

Intermod distortion (IMD₃)

≥ 32 dBc

≥ 41 dBc

≥ 48 dBc

≥ 60 dBc

≥ 39 dBc

≥ 47 dBc

≥ 58 dBc

≥ 64 dBc

Measured DC to 540 MHz

Measured DC to 135 MHz

Fc = 100 MHz ± 500 KHz: 1.0 Vpp, 0.5 Voff (SE) or 2.0 Vpp, 0.5 Vcm (Diff)

Fc = 100 MHz ± 500 KHz: 1.0 Vpp, 0 Voff (SE) or 2.0 Vpp, 0 Vcm (Diff)

Fc = 10 MHz ± 500 KHz: 1.0 Vpp, 0.5 Voff (SE) or 2.0 Vpp, 0.5 Vcm (Diff)

Fc = 10 MHz ± 500 KHz: 1.0 Vpp, 0 Voff (SE) or 2.0 Vpp, 0 Vcm (Diff)

Third order intercept (TOI)

< -56 dBc

< -71 dBc

< -76 dBc

< -79 dBc

< -59 dBc

< -72 dBc

< -78 dBc

<-81 dBc

Fc = 100 MHz ± 500 KHz: 1.0 Vpp, 0.5 Voff (SE) or 2.0 Vpp, 0.5 Vcm (Diff)

Fc = 100 MHz ± 500 KHz: 1.0 Vpp, 0 Voff (SE) or 2.0 Vpp, 0 Vcm (Diff)

Fc = 10 MHz ± 500 KHz: 1.0 Vpp, 0.5 Voff (SE) or 2.0 Vpp, 0.5 Vcm (Diff)

Fc = 10 MHz ± 500 KHz: 1.0 Vpp, 0 Voff (SE) or 2.0 Vpp, 0 Vcm (Diff)

Output phase noise (100 MHz output)

> 27 dBm

> 34 dBm

> 37 dBm

> 38 dBm

> 27 dBm

> 34 dBm

> 37 dBm

> 39 dBm

1 kHz offset

10 kHz offset

100 kHz offset

1 Mhz offset

-130 dBc/Hz

-135 dBc/Hz

-137 dBc/Hz

-150 dBc/Hz

-152 dBc/Hz

≤ -151 dBm/Hz

-130 dBc/Hz

-135 dBc/Hz

-137 dBc/Hz

-150 dBc/Hz

-152 dBc/Hz

≤ -151 dBm/Hz

10 Mhz offset

Noise ﬂoor

100 MHz tone, spot noise

measured at 133 MHz

Figure 15. Typical Channel 3, 10 MHz tone spectrum

Figure 16. Typical Channel 3, 500 MHz tone spectrum

18 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Spectral Characteristics (Chan 3) (cont’d)

Figure 17. Typical 2nd harmonic distortion, channel 3, single-ended

Figure 18. Typical 3rd harmonic distortion, channel 3, single-ended

19 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Spectral Characteristics (Chan 3) (cont’d)

Figure 19. Typical 2nd harmonic distortion, channel 3, differential

Figure 20. Typical 3rd harmonic distortion, channel 3, differential

20 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Spectral Characteristics (Chan 3) (cont’d)

Figure 21. Typical Channel 3, 100 MHz two tone intermod

Figure 22. Typical Channel 3 noise floor

Figure 23. Typical pahse noise, channel 3

21 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

Modulation Format Speciﬁc Data

Typical EVM performance ¹

802.11ax

EVM (80MHz, 1024 QAM)

LTE/LTE advanced

0.2%

EVM (20MHz, 64 QAM)

EVM (100MHz, 64 QAM)

OFDM

0.075%

0.3%

EVM (700MHz, 64 QAM)

0.7%

1. With differential outputs and matched cables. Individual channel adjustments for gain and delay may be required to achieve best EVM performance

Clocks

Sample Clock

User sample rate (F_s) - option B12

User sample rate (F_s) - option B50

1 Sa/s to 320 MSa/s, 1µSa/s resolution

1 Sa/s to 1.28 GSa/s, 1µSa/s resolution

Reference Clock

Reference clock sources

Reference clock lock range

PXIe_CLK100 (100 MHz)

±25 ppm

Sequencer, Triggers

Sequencer

Waveform memory (option dependent)

Waveform granularity (quantum)

Waveform segment length

Minimum - burst

Up to 500 MSa/ch

4 samples

12 samples

Minimum - looped

512 samples

Maximum

2,145,300,000 samples

Maximum segments per sequence

Maximum number of sequences

2²⁷

2²⁵

Input Triggers

Number of triggers

Trigger sources

Trigger types

12 hardware and 12 software

Software, PXI_TRIG, PXI_STAR, DSTARB, Ext 1, Ext 2, and immediate

Start and sequence

Positive or negative

3.125 ns

Trigger polarity

Trigger timing resolution

Trigger Jitter

±3.125 ns

Trigger latency

Correction ﬁlter off

Correction ﬁlter on

Minimum trigger width

Programmable delay

Range

322 ns + (24 * User sample period in ns)

2960 ns + (24 * User sample period in ns)

20 ns

10 s

Resolution

3.125 ns

22 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

Markers

Maximum number of markers

Marker type

8 per channel

Sample (data marker)

Marker polarity

Positive or negative

Marker destinations

Marker placement accuracy

Marker to waveform jitter

Programmable delay

Range

PXI_TRIG, PXI_STAR, PXIe_DSTARC, Ext 1, and Ext 2

3.125 ns

Up to 3.125 ns, depending on waveform sample rate

20 ms

Resolution

3.125 ns

Channel Markers

Number of markers

Marker type

Up to 3 depending on number of available channels

Precise data marker (timed precisely with waveform characteristics of another output channel)

Positive or negative

Marker polarity

Marker destinations

Marker placement accuracy

Marker on channels 1 and 2

Marker on channel 3

Marker to waveform jitter

Programmable delay

Range

Analog output channels not being used for waveform output

20 ps

40 ps

25 ps

±0.5 x (user sample period)

.001 ps

Resolution

Marker width

4 user samples

Ext1 and Ext2 Characteristics

Direction Control

Input or output (conﬁgurable)

Output level

0 to 3.3 V

50 Ω

Output impedance (output mode)

Maximum input level

Input impedance (input mode)

Programmable trigger input threshold

Range

±5.5 V

10 kΩ

-4 to 4V

10 mV

Programming resolution

Accuracy

±100 mV

100 mV

10 ns

Minimum input swing

Minimum input pulse width

23 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Technical Speciﬁcations

Environmental Characteristics ^1,2

Operating and Storage Conditions

Operating

Storage

Temperature³

0˚C to 50˚C

-40˚C to 70˚C

Altitude

Up to 10,000 ft (3048 m)

Up to 15,000 ft (4572 m)

Humidity

Type-tested at 95%, +40˚C (non-condensing)

Calibration interval

Warm-up time

Vibration

1 year

30 minutes

Operating random vibration: type-tested at 5 to 500 Hz, 0.21 g rms

Survival random vibration: type-tested at 5 to 500 Hz, 2.09 g rms

Regulatory Characteristics

Safety

Complies with the essential requirements of the European Low Voltage Directive as well as the current versions of the following standards (dates and

editions are cited in the Declaration of Conformity):

– IEC/EN 61010-1

– Canada: CSA C22.2 No. 61010-1

– USA: UL std no. 61010-1

EMC

Complies with the essential requirements of the European EMC Directive as well as the current editions of the following standards (dates and editions are

cited in the Declaration of Conformity):

– IEC/EN 61326-1

– CISPR Pub 11 Group 1, class A

– AS/NZS CISPR 11

– ICES/NMB-001

This ISM device complies with Canadian ICES-001.

Cet appareil ISM est conformea la norme NMB-001 du Canada

South Korean Class A EMC declaration

Information to the user:

This equipment has been conformity assessed for use in business environments. In a residential environment this equipment may cause radio

interference.

– This EMC statement applies to the equipment only for use in business environment.

사 용 자 안 내 문

이 기기는 업무용 환경에서 사용할 목적으로 적합성평가를 받은 기기로서

가정용 환경에서 사용하는 경우 전파간섭의 우려가 있습니다.

※ 사용자 안내문은 “업무용 방송통신기자재”에만 적용한다.

1. Samples of this product have been type tested in accordance with the Keysight Environmental Test Manual and verified to be robust against the environ-

mental stresses of Storage, Transportation and End-use; those stresses include but are not limited to temperature, humidity, shock, vibration, altitude and

power line conditions.

2. Test methods are aligned with IEC 60068-2 and levels are similar to MIL-PRF-28800F Class 3.

3. De-rate max temperature by 5 °C above 2000 m.

24 | Keysight | M9336A I/Q Arbitrary Waveform Generator - Data Sheet

Ordering Information

Software information

Hardware information

Supported operating systems

Microsoft Windows 7 (64-bit only)

Microsoft Windows 10 (64-bit only)

Model

Description

M9336A

PXIe I/Q arbitrary waveform generator:

500 MHz BW, 16-bit, 3 scalar channels

Standard compliant drivers

IVI.NET, IVI-C, and LabVIEW

Supported application

development environments

(ADE)

LabVIEW, MATLAB, Visual Studio.NET

(C/C++, C#, VB.NET), Command Expert

M9336A-001

M9336A-B12

M9336A-B50

M9336A-M02

M9336A-M04


型号：	M9336A-M02
厂家：	Keysight Technologies
描述：	M9336A PXIe I/Q Arbitrary Waveform Generator
文件：	总25页 (文件大小：6432K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

M9336A-M02 [KEYSIGHT]

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