產品明細

AWG-5000 脈波產生器

    產品簡述
    ♦ 取樣率: 6.16 GS/s
    ♦ 垂直解析可達16 Bit
    ♦ Edge time最小可達 110 ps
    ♦ 最大動態範圍可達 5 Vpp (50 ohms)
    ♦ 記憶深度: 每個通道高達4 Gpts
    ♦ 最多可提供32個數位通道與類比通道同步
    ♦ 軟體使用者介面: AWG模式使用Simple TrueArb Rider; AFG模式使用Simple Rider

      產品詳細介紹Product Introduction

      ARB RIDER AWG-5000 PULSE GENERATOR

      Fast Pulse Generator – up to 5Vpp amplitude

      The ARB Rider AWG-5000 Series is the world’s fastest 2, 4 and 8 channels pulse generators equipped with a 16 bit resolution Digital to Analog converter. Single pulse or double pulse can be programmed in few seconds thanks to the easy-to-use user interface.  AWG-5000 Pulse Generator series offers 6.16 Gs/s update rate, 5Vpp output voltage range, 110 ps Rise/Fall time, and up to 4 GSamples memory depth, making this product the ideal choice for Automotive, Aerospace & Defense, Big Physics and Semiconductor Test applications.
      Up to 8 analog channels per unit and up to 32 digital lines (TTL or LVDS standards) allow the user to create a mixed-signal generation setup to generate analog and digital stimuli.

      No Compromise on analog performances: the fast rise time of 110ps can be achieved at a maximum amplitude of 5Vpp

      Moreover, the Serial Data Pattern Generator option, allows you to generate a stream of binary information through the front end SMA connectors with an update rate of 1.54 Gbps: built-in PRBS sequences, modulation features, transition shaping, and the flexibility of a powerful analog front-end makes the SPG the perfect tool for the most challenging applications.

      A dedicated intra-chassis synchronization bus, allow multi-instrument synchronization up to 4 units: 32 analog channels and 128 digital channels for the most powerful mixed-signal generator in the world.


      Models

      ModelsNo. of ChannelsMin. Rise/Fall Time (20%-80%)AmplitudeBaseline OffsetMin. Pulse Width
      AWG-50622110 ps5Vpp into 50 Ohm+/-2.5V230 ps
      AWG-5062D2110 ps1.5Vpp into 50 Ohm+/-2V230 ps
      AWG-50644110 ps5Vpp into 50 Ohm+/-2.5V230 ps
      AWG-5064D4110 ps1.5Vpp into 50 Ohm+/-2V230 ps
      AWG-50688110 ps5Vpp into 50 Ohm+/-2.5V230 ps
      AWG-5068D8110 ps1.5Vpp into 50 Ohm+/-2V230 ps
      AWG-5032D2200 ps1.5Vpp into 50 Ohm+/-2V460ps
      AWG-5034D4200 ps1.5Vpp into 50 Ohm+/-2V460ps
      AWG-5038D8200 ps1.5Vpp into 50 Ohm+/-2V460ps

      Pulses for All Your Needs

      Whether it is generating a complex pulse train, a series of radar pulses, pulsed RF signals with impairments, Gaussian pulses,multi-level pulses, double pulses for IGBT/Mosfet experiments, pulses for Advanced Research and Quantum computing, the AWG-5000 is the ideal partner for all your most complex tests and cutting-edge applications.

      Highlights

      • Up to 5Vpp into 50 Ohm Pulse Amplitude with ± 2.5V hardware offset

      • 110 ps Rise and Fall Time

      • Minimum Pulse Width: 230 ps

      • Shape easily your Pulse Transitions


      Features
      • Sample rate can be programmed in from 1 S/s up to 6.16 GS/s (12.32 GS/s in RF mode in 506x models only), with 16-bit vertical resolution, ensures exceptional signal integrity

      • Arbitrary waveform memory up to 4 Gpts for each analog channel

      • Mixed Signal Generation – 2, 4 or 8 Analog channels with 8, 16 or 32 synchronized Digital Channels for debugging and validating digital design.

      • Three operation modes – Simple Rider AFG (DDS AFG mode), True Arb (variable clock Arbitrary AWG mode) and SPG (Serial Pattern Generator).

      • Digital outputs provide up to 1.54 Gb/s data rate in LVDS format. LVDS to LVTTL adapter is available

      • Advance sequencer with up to 16384 user defined waveforms provides the possibility of generating complex signal scenarios with the most efficient memory usage

      • Windows based platform with 7in touch screen, front panel buttons and knob

      • Compact form factor, convenient for bench top and fully fit with 3U – 19” rackmount standard

      • LAN,USB-TMC and GPIB interfaces for remote control


      Apllication Areas

       

      Quantum Computing and RF Wireless

      The AWG-5000 is the right choice for the frontier of science and technology experiments and cutting-edge challenges like Quantum, High Energy Physics, Optical and RF Wireless Communication.

      The AWG-5000 Series instrument can create virtually any signal – analog or digital, ideal or distorted, standard or custom. You can easily build complex RF/IF/IQ waveform or generate serial data streams on your PC and transfer it to the AWG.

      Highlights

      • Minimum delay between Trigger In and Analog Out

      • Up to 32 analog channels and 128 digital channels fully synchronized

      • Built-in sequencer with conditional/unconditional/dynamic jump features, two independent Trigger Inputs, up to 4 Marker outputs

      Radar, LiDAR Design and EW

      Wideband radar and electronic warfare systems need high fidelity signals to replicate real-world situations and complex environment scenarios.

      Moreover, nowadays automotive solutions need to create accurate and reliable tests to prove safety under a variety of test conditions is key: LiDAR is one of the strategic components for these kinds of solutions.

      Key Features

      • Generate Radar  test signals with excellent spurious performance

      • Create Electronic Warfare complex scenarios with up to 16384 sequencer entries and Advanced Sequencer conditional/unconditional jumps.

      • Build up LiDAR signal testing for aerospace & defense, automotive and mobile devices solutions

      • Create test waveforms using the Waveform Editor software or import them using third-party applications like MatLab, Labview, .NET languages, etc.

      Automotive

      Today’s cars are including a lot of highly sophisticated electronic control unit with very sensitive electronic components. The Arb Rider 506x(D) and 503x (with x=2,4,8) combining up to 6.16 GS/s with 16-bits vertical resolution, represents an ideal tool for successfully addressing the new testing challenges in automotive.

      Highlights

      • EMI debugging, troubleshooting and testing

      • Electrical standards emulation up to 5V


      IoT and Ind 4.0 perfect RF Modulator


      Arb and Function Riders will be the iconic instrument for these applications. The possibility to emulate complex RF I/Q modulation for simulation and Test vs wireless devices or working on Internet of things of industry 4.0 applications. Each engineer may use the possibility to import waveform to emulate devices under test, impose distortion on waveform (such noise) to test the ability of devices to be compliant to the standards.


      Research Applications

      Research centers and Universities, are key users of Arb Rider generators‘s series.
      Complex waveform and/or sophisticated Pulses emulation based on variable edges or multilevel could be perfectly created. The combination of fast edge generation, excellent dynamic range and easy to use user interface meet perfectly scientists and engineers working on large experiments such Accelerators, Tokamak or synchrotrons to emulate signals without creating specifics test boards.

      Highlights

      • Emulation of detectors

      • Emulation of signal sources adding noise

      • Generation/playback of real-world signals

      • Emulation of long PRBS sequences

      • Modulating and driving laser diode


      Aerospace and Defense applications

      Electronic warfare signals driven by Radar or Sonar systems perfectly match with these generators. Large BW Riders can be used on digital modulation systems for Radio Applications or others I/Q signal modulation.
      Pulses may be easily generated for applications such Pulse Electron Beam or X Ray Sources, Flash Xray Radiography, Lighting pulse simulators, high Power Microwave modulators.

      Highlights

      • Frequency response, intermodulation distortion and noise-figure measurements

      • Phase Locked Loop (PLL) pull-in and hold range characterization

      • Radar base-band signals emulation


      Semiconductors Test

      Emulation of complex signals generated with inclusion of noise or distortions may became an excellent way to provide Compliance Components Test to help semiconductors engineers. The fast edges and pulse generation can be used to provide characterization in fast power devices.

      Highlights

      • Clock and Sensor signals generation

      • MOSFET gate drive amplitude signal emulation

      • Power up sequences of IC using the low impedance feature (5 Ω output impedance)

       

      Waveform Editor: Powerful and Easy

      The Waveform Editor allows you to create easily the most complex shapes for your radar pulses, physical research pulses, real-world signals, and complex environment signals. It is included in the standard software package.

      Key Features

      • Generate easily the most complex analog and digital signals

      • Create your waveforms remotely on your PC

      • Full integration with the True-Arb software


      Multi-Instrument Synchronization

      You can synchronize up to 4 units to build a system made of 32 analog channels and 128 digital channels fully synchronized and integrated with the True-Arb software.

      Main Features

      • Synchronize up to 4 units: 32 Analog channels and 128 Digital channels

      • Affordable price per channel

      • Easy to use Multi-Instrument control through True-Arb software


      Specifications

      General Specifications
      Model No.AWG-5062
      AWG-5062D
      AWG-5032D
      AWG-5064
      AWG-5064D
      AWG-5034D
      AWG-5068
      AWG-5068D
      AWG-5038D
      Operation ModeAFG Mode
      True Arb Mode
      SPG Mode
      Number of Channels
      Analog
      248
      Digital
      0/8 opt.0/8/16 opt.0/8/16/24/32 opt.
      Markers
      124

      Model No.AWG-5062
      AWG-5064
      AWG-5068
      AWG-5062D
      AWG-5064D
      AWG-5068D

      AWG-5032D
      AWG-5034D
      AWG-5038D
      Output Channels
      Output type
      Single ended DC coupledDifferential DC coupled
      Output impedance
      Single ended: 50 ΩSingle ended: 50 Ω
      Differential: 100 Ω
      Connectors
      SMA on front panel
      DC Amplitude
      Amplitude range
      ±2.5 V (into 50 Ω)±0.75 V Se. (into 50 Ω)
      ±1.5 V Diff. (into 100 Ω)
      Resolution
      100µV (nom), 5 digits
      Amplitude accuracy (guaranteed)
      ±(1% of |setting| + 5mV)±(1% of |setting| + 2mV)1
      DC Baseline Hardware Offset
      (Common mode offset)
      Resolution
      < 4 mV or 4 digits
      Range (50 Ω into 50 Ω)
      -2.5 V to +2.5 V -2 V to +2 V
      Range (50 Ω into High Z load)
      -2.5 V to +2.5 V -4 V to +4 V
      Accuracy (50 Ω into 50 Ω) (guaranteed)
      ± (1% of |setting| + 5 mV)
      AC Accuracy (1 kHz sine wave, 0 V offset, > 5 mVp-p amplitude, 50 Ω load) (guaranteed)± (1% of setting [Vpp] + 5mV)1
      1 The specification is guarantee in the range 0% to 90% of full sale output
      True Arb - Baseband mode specifications
      Model No.AWG-5062
      AWG-5064
      AWG-5068
      AWG-5062D
      AWG-5064D
      AWG-5068D

      AWG-5032D
      AWG-5034D
      AWG-5038D
      General specifications
      Operating Mode
      Variable clock (True Arbitrary) – Baseband mode
      Sample Rate
      1 S/s to 6.16 GS/s (AWG-506x/506xD, x = 2,4,8)
      1 S/s to 3 GS/s (AWG-503xD, x = 2,4,8)
      Sin(x)/x -3dB bandwidth
      2.72 GHz @ 6.16GS/S (AWG-506x/506xD)
      1.32 GHz @ 3 GS/S (AWG-503xD)
      Run Modes
      Continuous, Triggered Continuous, Single/Burst, Stepped, Advanced
      Vertical Resolution
      16 bit
      Max Waveform Length
      2G samples per channel (4G samples optional
      Waveform Granularity
      1 if the entry length is > 416 samples
      32 if entry length is ≥ 128 and ≤ 416 samples
      Sequence Length
      1 to 16384
      Sequence Repeat Counter
      1 to 4294967294 or infinite
      Timer
      Range
      20 ns to 1.39 seconds
      Resolution
      ± 1 sampling clock cycle
      Analog Channel to Channels skew
      Range
      0 to 2.63 us
      Resolution
      100 fs
      Accuracy
      ±(1% of setting + 20 ps)
      Initial skew
      < 20 ps
      Calculated bandwidth
      (0.35 / rise or fall time)
      ≥ 2 GHz≥ 2.2 GHz (AWG–506xD)
      ≥ 1.1 GHz (AWG-503xD)
      SFDR @ 100 MHz (measured across DC to Fs/2, excluding fsa - 2*fout and fsa- 3*fout and excluding harmonic.

      Fsa= 6.16 Gsa/s for AWG-506x(D) models
      Fsa= 3 Gsa/s for AWG-503xD models
      < -80 dBc< - 90 dBc
      SFDR (measured across DC to Fs/2, excluding fsa - 2*fout and fsa- 3*fout and excluding harmonic.

      Fsa= 6.16 Gsa/s for AWG-506x(D) models
      Fsa= 3 Gsa/s for AWG-503xD models
      1μHz to ≤ 600MHz: < -80dBc
      600MHz to ≤ 1.5GHz: < -75dBc
      1.5GHz to ≤ 2GHz: < -65dBc
      2GHz to ≤ 3GHz: < -55dBc
      1μHz to < 100MHz: < -90dBc
      100MHz to ≤ 600MHz: < -82dBc
      600MHz to ≤ 1.5GHz: < -75dBc
      1.5GHz to ≤ 2GHz: < -70dBc
      2GHz to ≤ 3GHz: < -62dBc
      Rise/fall time (1 Vp-p single-ended 10% to 90%)≤ 175 ps≤ 155 ps (AWG–506xD)
      ≤ 320 ps (AWG – 503xD)
      Rise/fall time (1 Vp-p single-ended 20% to 80%)≤ 110 ps≤ 100 ps (AWG–506xD)
      ≤ 200 ps (AWG–503xD)
      Overshoot (1 Vp-p single-ended)<5%<6%
      Random jitter on clock pattern (rms, typical)< 2 ps
      True Arb - RF Mode specifications (optional for AWG–506x/506xD only)
      Model No.AWG-5062
      AWG-5064
      AWG-5068
      AWG-5062D
      AWG-5064D
      AWG-5068D
      General specifications
      Operating Mode
      Variable clock (True Arbitrary) – RF mode
      incluOutput Sample Rate
      8.5 GS/s to 12.32 GS/s
      Sin(x)/x
      5.04 Ghz @ 12.32GS/S
      RF Modulation
      I/Q quadrature
      RF Carrier count per output channel
      Single Carrier (2 components I0,Q0 for channel)
      Double Carrier (4 components, I0,Q0 and I1,Q1 for channel)
      RF Carrier Frequency range
      0 up to 6 GHz
      RF Carrier Frequency resolution
      1 mHz
      RF Carrier Phase
      Programmable
      I/Q Component Data Rate
      1/8 of the Output Sample rate
      I/Q Component Prescaler
      0 to 2^32
      Run Modes
      Continuous, Triggered Continuous, Single/Burst, Stepped, Advanced
      I/Q Component Vertical Resolution
      16 bit
      I/Q Component Waveform Length
      32M to 500M samples for component
      (up to 1G samples optional)
      I/Q Component Waveform Granularity
      1 if the entry length is > 104 samples
      8 if entry length is ≥ 32 and ≤ 104 samples
      Sequence Length
      1 to 16384
      Sequence Repeat Counter
      1 to 4294967294 or infinite
      Timer
      Range
      20 ns to 1.39 seconds
      Resolution
      ± 1 Component sampling clock cycle
      I/Q Component to Component skew
      Range
      0 to [16200 * 8/Output Sampling Clock] s
      Resolution
      [8/Output Sampling Clock] s
      Accuracy
      ±(1% of setting + 20 ps)
      Initial skew
      < 20 ps
      AFG Mode Specifications
      Model No.AWG-5062
      AWG-5064
      AWG-5068
      AWG-5062D
      AWG-5064D
      AWG-5068D

      AWG-5032D
      AWG-5034D
      AWG-5038D
      General Specifications
      Amplitude
      Range
      0 to 5Vpp (into 50 Ω)0 to 3Vpp Diff. (into 100 Ω)
      0 to 1.5Vpp Se. (into 50 Ω)
      Resolution
      100µV (nom), 5 digits
      Operating mode
      DDS mode
      Standard Waveforms
      Sine, Square, Pulse, Ramp, more (Noise, DC, Sin(x)/x, Gaussian, Lorentz, Exponential Rise, Exponential Decay, Haversine
      Run Modes
      Continuous, modulation, sweep, burst
      Arbitrary Waveforms
      Vertical resolution: 16-bit
      Waveform length: 16,384 points
      Internal Trigger Timer
      Range
      10.4 ns to 88 s
      Resolution
      80 ps
      Accuracy
      ±(0.1% setting + 5 ps)
      Sine Waves
      Frequency Range Sine (50 Ω into 50 Ω) 2
      1 μHz to ≤ 1 GHz: 5Vpp
      1 GHz to ≤ 2 GHz: 4Vpp
      AWG–506xD:
      1 μHz to ≤ 2 GHz: 3Vpp Diff.
      1 μHz to ≤ 2 GHz: 1.5Vpp Se.

      AWG–503xD:
      1 μHz to ≤ 1 GHz: 3Vpp Diff.
      1 μHz to ≤ 1 GHz: 1.5Vpp Se.
      2 Amplitude doubles on HiZ load
      Flatness
      DC to 2 GHz: ±0.5 dB
      (1 Vpp, relative to 1 kHz)
      AWG–506xD:
      DC to 2 GHz: ±0.5 dB
      (1 Vpp diff., relative to 1 kHz)

      AWG–503xD:
      DC to 1 GHz: ±0.5 dB
      (1 Vpp diff., relative to 1 kHz)
      Harmonic Distortion (1 Vp-p)
      1μHz to ≤ 20kHz < -75dBc
      20kHz to ≤ 400MHz < -70dBc
      400MHz to ≤ 1GHz < -60dBc
      1GHz to ≤ 2GHz < -55dBc
      -
      Total Harmonic Distortion (1 Vp-p)
      10 Hz to 20 kHz < 0.05%-
      Spurious (measured across DC to 3.08Ghz for AWG-506x/606xD models and DC to 1.5Ghz for AWG-503x models) 3
      1μHz to ≤ 500MHz: < -75dBc
      500MHz to ≤ 1.5GHz: < -70dBc
      1.5 GHz to ≤ 2GHz: < -55 dBc
      1μHz to ≤ 250MHz: < -85dBc
      250MHz to ≤ 500MHz: < -80dBc
      500MHz to ≤ 1.5GHz: < -70 dBc
      1.5 GHz to ≤ 2GHz: < -60 dBc
      3 For AWG-5062/5064/5068 models the spurious are evaluated @ 1Vpp single ended nominal output amplitude. For AWG5062D/5064D/5068D models and 5032D/5034D/5038D the SFDR is evaluated @ 1Vpp differential nominal output amplitude provided to the spectrum analyzer through a Minicircuit TC1-1-13M+ balun.
      Phase Noise (1 Vp-p, 10 kHz offset)
      20 MHz: < -127 dBc/Hz typ.
      100 MHz: < -123 dBc/Hz typ.
      1 GHz: < -105 dBc/Hz typ.
      Square Waves
      Frequency Range
      1μHz to ≤ 770 MHzAWG–506xD:
      1 μHz to ≤ 770 MHz

      AWG–503xD:
      1 μHz to ≤ 385 MHz
      Rise/fall time (10% to 90%)
      400 ps (AWG–506x/506xD)
      800 ps (AWG–503xD)
      Rise/fall time (20% to 80%)
      300 ps (AWG–506x/506xD)
      600 ps (AWG–503xD)
      Overshoot (1 Vp-p)
      <2%
      Jitter (rms)
      <2 ps
      Pulse Waves
      Frequency Range
      1μHz to ≤ 770 MHzAWG–506xD:
      1 μHz to ≤ 770 MHz

      AWG–503xD:
      1 μHz to ≤ 385 MHz
      Pulse width
      500 ps to (Period – 500 ps)4 (AWG–506x/506xD)
      1 ns to (Period – 1 ns)5 (AWG–503xD)
      4 Below 500 ps width, the pulse amplitude will have some reduction respect to the set value
      5 Below 1ns width, the pulse amplitude will have some reduction respect to the set value
      Pulse width Resolution
      20 ps or 15 digits
      Pulse duty
      0.1% to 99.9% (limitations of pulse width apply)
      Leading/trailing edge transition time (10% to 90%)
      400 ps to 1000 s (AWG–506x/506xD)
      800 ps to 1000 s (AWG–503xD)
      Leading/trailing edge transition time (20% to 80%)
      300 ps to 1000s (AWG–506x/506xD)
      600 ps to 1000s (AWG–503xD)
      Transition time Resolution
      2 ps or 15 digits
      Overshoot (1 Vp-p)
      < 2%
      Jitter (rms, with rise and fall time ≥ 400ps)
      <2 ps
      Double Pulse Waves
      Frequency Range
      (Where Vpp= |Vpp1| + |Vpp2|)
      1μHz to ≤ 385 MHz: 10VppAWG–506xD:
      1 μHz to ≤ 385 MHz: 6Vpp Diff.
      1 μHz to ≤ 385 MHz: 3Vpp Se.

      AWG–503xD:
      1 μHz to ≤ 192.5MHz: 6Vpp Diff.
      1 μHz to ≤ 192.5 MHz: 3Vpp Se.
      Other Pulse Parameters
      Same as Pulse Waves
      Ramp Waves
      Frequency Range
      1 μHz to 75 MHz (AWG–506x/506xD)
      1 μHz to 37.5 MHz (AWG–503xD)
      Linearity (< 10 kHz, 1 Vp-p, 100%)
      ≤ 0.1%
      Symmetry
      0% to 100%
      Other Waves
      Frequency Range
      Exponential Rise, Exponential Decay
      1 μHz to 75 MHz (AWG–506x/506xD)
      1 μHz to 37.5 MHz (AWG–503xD)
      Sin(x)/x, Gaussian, Lorentz, Haversine
      1 μHz to 150 MHz (AWG–506x/506xD)
      1 μHz to 75 MHz (AWG–503xD)
      Additive Noise
      Bandwidth (-3 dB)
      2 GHz
      Level
      0 V to 2.5 V - abs(carrier max value [Vpk])0 V to 0.75 V Single Ended - abs(carrier max value [Vpk])
      0 V to 1.5 V Differential - abs(carrier max value [Vpk])
      Resolution
      1 mV
      Arbitrary
      Number of Samples
      2 to 16384
      Frequency range
      1 μHz to ≤ 770 MHz (AWG–506x/506xD)
      1 μHz to ≤ 385 MHz (AWG–503xD)
      Analog Bandwidth (-3 dB)
      950 MHz (AWG–506x/506xD)
      470 MHz (AWG–503xD)
      Rise/fall time (10% to 90%)
      400 ps (AWG–506x/506xD)
      800 ps (AWG–503xD)
      Rise/fall time (20% to 80%)
      300 ps (AWG–506x/506xD)
      600 ps (AWG–503xD)
      Jitter (rms)
      < 2 ps
      Frequency Resolution
      Sine, square, pulse, arbitrary, Sin(x)/X Gaussian, Lorentz, Exponential Rise, Exponential Decay, Haversine
      1 μHz or 15 digits
      1 μHz or 14 digits
      Frequency Accuracy
      Non-ARB
      ± 2.0 ppm of setting | ± 500 ppb of setting (Opt.)
      ARB
      ± 2.0 ppm of setting ±1 μHz | ± 500 ppb of setting ±1 μHz(Opt.)
      Modulations
      Amplitude Modulation (AM)
      Carrier waveforms
      Standard waveforms (except Pulse, DC and Noise), ARB
      Modulation source
      Internal or external
      Internal modulating waveforms
      Sine, Square, Ramp, Noise, ARB
      Modulating frequency
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Depth
      0.00% to 120.00%
      Frequency Modulation (FM)
      Carrier waveforms
      Standard waveforms (except Pulse, DC and Noise), ARB
      Modulation source
      Internal or external
      Internal modulating waveforms
      Sine, Square, Ramp, Noise, ARB
      Modulating frequency
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Peak deviation
      DC to 2 GHz (AWG–506x/506xD)
      DC to 1 GHz (AWG–503xD)
      Phase Modulation (PM)
      Carrier waveforms
      Standard waveforms (except Pulse, DC and Noise), ARB
      Modulation source
      Internal or external
      Internal modulating waveforms
      Sine, Square, Ramp, Noise, ARB
      Modulating frequency
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Phase deviation range
      0° to 360°
      Frequency Shift Keying (FSK)
      Carrier waveforms
      Standard waveforms (except Pulse, DC and Noise), ARB
      Modulation source
      Internal or external
      Internal modulating waveforms
      Square
      Key rate
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Hop frequency
      DC to 2 GHz (AWG–506x/506xD)
      DC to 1 GHz (AWG–503xD)
      Number of keys
      2
      Phase Shift Keying (PSK)
      Carrier waveforms
      Standard waveforms (except Pulse, DC and Noise), ARB
      Modulation source
      Internal or external
      Internal modulating waveforms
      Square
      Key rate
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Hop phase
      0° to +360°
      Number of keys
      2
      Pulse Width Modulation (PWM)
      Carrier waveforms
      Pulse
      Modulation source
      Internal or external
      Internal modulating waveforms
      Sine, Square, Ramp, Noise, ARB
      Modulating frequency
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Deviation range
      0% to 50% of pulse period
      Sweep
      Type
      Linear, Logarithmic, staircase, and user defined
      Waveforms
      Standard waveforms (except Pulse, DC and Noise), ARB
      Sweep time
      30 ns to 2000 s
      Hold/return times
      0 to (2000 s – 30 ns)
      Sweep/hold/return time resolution
      15 ns or 12 digits
      Total sweep time accuracy
      ≤ 0.4%
      Start/stop frequency range
      AWG–506x/506xD:
      Sine: 1 μHz to 2 GHz, Square: 1 μHz to 770 MHz

      AWG–503xD:
      Sine: 1 μHz to 1 GHz, Square: 1 μHz to 385 MHz
      Trigger source
      Internal/External/Manual
      Burst
      Waveforms
      Standard waveforms (except DC and Noise), ARB
      Type
      Trigger or gated
      Burst count
      1 to 4,294,967,295 cycles or Infinite
      Data Pattern Generator (DPG) Specifications – Optional
      for AWG 506X/506XD models only (where X= 2,4,8)
      Model No.AWG-5062
      AWG-5064
      AWG-5068
      AWG-5062D
      AWG-5064D
      AWG-5068D
      General Specifications
      Operating mode
      NRZ, RZ or R1 bitstream Pattern generator
      Pattern types
      Clock Pattern, Custom Pattern, PRBS pattern, Go-Through Pattern, Pulse Pattern
      Run Modes
      Continuous, modulation, burst (Triggered, Gated, Continuous triggered)
      Internal Trigger Timer
      Range
      10.4 ns to 88 s
      Resolution
      80 ps
      Accuracy
      ±(0.1% setting + 5 ps)
      Transition Specifications
      Tansition peculiarity
      Arbitrarily user defined transition shapes
      Programmable duration for any transition
      Transitions types
      Arbitrary, predefined
      Transitions memory length
      64 points
      Predefined transition Shapes
      Sine, Square, Pulse, Ramp_up, Ramp_down, DC, Sin(x)/x, Gaussian, Lorentz, Exponential Rise, Exponential Decay, Haversine
      Transition duration[0-100%]
      500ps to Symbol duration for Custom,PRBS and Go-Through pattern
      500ps to Period/2 for Clock Pattern
      500ps to (Period-500ps) for Pulse Pattern
      Clock Pattern
      Max clock pattern frequency
      750 MHz
      Pattern levels
      2 levels
      Overshoot (1 Vp-p)
      < 2%
      Jitter (rms)
      < 2 ps
      Custom Pattern
      Max custom pattern rate
      Up to 1,5 Gbaud
      Pattern levels
      2, 3 or 4 levels
      Predefined custom patterns
      Zero, one, clock, counter
      Pattern memory
      Up to 2 MBit (2 levels)
      Up to 1 MSymbols (3 or 4 levels)
      Pattern length resolution
      1 bit
      Min pattern length
      4 bits
      Overshoot (1 Vp-p)
      < 2%
      PRBS Pattern
      Max PRBS pattern rate
      Up to 1,5 Gbaud
      Pattern levels
      2 levels
      PRBS types
      PRBS -7,9,11,15,23,31
      Overshoot (1 Vp-p)
      < 2%
      Go-Through Pattern
      Max Go-Through pattern rate
      Up to 1,5 Gbaud
      Pattern levels
      2,3 or 4 levels
      Max External Pattern Rate
      Up to 10Mbit/s
      Overshoot (1 Vp-p)
      < 2%
      Pulse Pattern
      Max Pulse pattern frequency
      Up to 1 GHz
      Pattern levels
      2 Levels
      Min Rise/Fall time (0-100%)
      500 ps
      Min Pulse Width
      1 ns
      Overshoot (1 Vp-p)
      < 2%
      Pattern Modulation
      Amplitude Modulation (AM) 
      Carrier patterns
      All types
      Modulation source
      Internal or external
      Internal modulating waveforms
      Sine, Square, Triangular, Ramp_up, Ramp_down, DC, Sin(x)/x, Gaussian, Lorentz, Exponential Rise, Exponential Decay, Haversine, Noise, ARB
      Modulating frequency
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Depth
      0.00% to 120.00%
      Frequency Modulation (FM)
      Carrier patterns
      All types
      Modulation source
      Internal or external
      Internal modulating waveforms
      Sine, Square, Triangular, Ramp_up, Ramp_down, DC, Sin(x)/x, Gaussian, Lorentz, Exponential Rise, Exponential Decay, Haversine, Noise, ARB
      Modulating frequency
      Internal: 500 μHz to 61 MHz, External: 10 MHz max
      Peak deviation
      DC to 300 MSymbols/s
      Phase Modulation (PM)
      Carrier patterns
      All types
      Modulation source
      Internal or external
      Internal modulating waveforms
      Sine, Square, Pulse, Ramp_up, Ramp_down, DC, Sin(x)/x, Gaussian, Lorentz, Exponential Rise, Exponential Decay, Haversine, Noise, ARB
      Modulating frequency
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Phase deviation range
      0° to 360°
      Frequency Shift Keying (FSK) 
      Carrier patterns
      All types
      Modulation source
      Internal or external
      Internal modulating waveforms
      Square
      Key rate
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Hope Symbol Rate
      1uSymbols/s to 1.5 GSymbols/s for Custom and PRBS
       pattern
      1uHz to 750 MHz for Clock pattern
      Number of keys
      2
      Phase Shift Keying (PSK) 
      Carrier patterns
      All types
      Modulation source
      Internal or external
      Internal modulating waveforms
      Square
      Key rate
      Internal: 500 μHz to 61 MHz, External: 10 MHz max.
      Hop phase
      0° to +360°
      Number of keys
      2
      Burst 
      Patterns
      All types
      Type
      Block mode or Bit mode
      Burst count
      1 to 4,294,967,295 cycles or Infinite
      Timing and Clock
      Sampling Rate
      Range
      AWG–506x/506xD:
      1 S/s Up to 6.16 GS/s
      (1 S/s to 12.32 GS/S in RF mode)

      AWG–503xD:
      1 S/s Up to 3GS/s
      Resolution
      32 Hz
      Accuracy
      ± 2.0 ppm | ± 500 ppb (Opt.)
      Digital outputs (Optional)
      Output Channels
      Connectors
      Mini-SAS HD connector on rear panel
      (custom pin-out)
      Number of connectors
      1,2,4
      Number of outputs
      8-bits,16-bits,32-bits
      Output impedance100 Ω differential
      Output typeLVDS
      Rise/fall time (10% to 90%)< 1 ns
      Jitter (rms)20 ps
      Maximum update rate1.54 Gbps per channel (AWG–506x/506xD)
      750 Mbps per channel (AWG–503xD)
      Memory depth512M Samples per digital channel (up to 1G optional)
      8 bit LVDS to LVTTL Converter Probe (Optional AT-DTLL8)
      Output connector20 position 2.54 mm 2 Row IDC Header
      Output typeLVTTL
      Output impedance50 Ω nominal
      Output voltage0.8V to 3.8V programmable in group of 8 bit
      Maximum Update Rate125 Mbps@0.8V and 400 Mbps@3.6V
      DimensionsW 52 mm – H 22 mm – D 76 mm
      Input ConnectorProprietary standard
      Cable Length1 meter
      Cable TypeProprietary standard
      Proprietary Mini SAS HD to SMA cable (Optional)
      Output connector SMA
      Output type LVDS
      Number of SMA 16 (8 bits)
      Cable type Proprietary standard
      Cable Length 1 meter
      Auxiliary input and output characteristics
      Sync in/out
      Connector type
      Infiniband 4X connector on rear panel (custom pinout)
      Master to Slave delay (typical)
      TBD
      Marker Output
      Connector type
      SMA on front panel
      Number of connectors
      1/2/4
      Output impedance
      50 Ω
      Output level (into 50 Ω)
      Voltage Window
      -0.5V to 1.65V
      Amplitude
      100 mVpp to 2.15 Vpp
      Resolution
      1 mV
      Accuracy
      ±(5% setting + 25 mV)
      Switching characteristics
      Max Update Rate (True Arb Mode)
      6.16 Gbps (AWG–506x/506xD)
      3 Gbps (AWG–503xD)
      Max Data Rate (True Arb Mode)
      >4 Gbps @ 1Vpp swing (AWG–506x/506xD)
      3 Gbps @ 1Vpp swing (AWG–503xD)
      Max Frequency (AFG Mode)
      96.5 MHz (continuous mode)
      Rise/fall time (10% to 90%, 2 Vpp)<150 ps
      Jitter (rms)<10 ps
      Marker out to analog channel skew
      Range
      True Arb Mode:0 to 2.3µs
      AFG Mode:0 to 11 sec. in Contin. Mode, 0 to 2.3 µs
      in Trig. Mode
      Resolution
      True Arb Mode:
      1/64 of DAC sampling period (AWG–506x/506xD)
      1/32 of DAC sampling period (AWG–503xD)
      AFG Mode:5 ps
      Accuracy
      ±(1% of setting + 5 ps)
      Initial skew
      < 20 ps
      Trigger/Event Inputs
      Connector
      SMA on the Front Panel
      Number of Trigger Inputs
      2 (Trig.in 1, Trig.in 2)
      Input impedance
      50Ω / 1kΩ
      Slope/Polarity
      Positive or negative or both
      Input damage level
      < -15 V or > +15 V
      Threshold control level
      -10 V to 10 V
      Resolution
      50 mV
      Threshold control accuracy
      ±(10% of |setting| + 0.2 V)
      Input voltage swing
      0.5 Vp-p minimum
      Minimum pulse width (1 Vp-p)
      3 ns
      Trigger/gate input to Analog Output delay
      Slow (synchronous) trigger
      AFG mode: < 355 ns (< 405 ns in triggered sweep mode)
      True Arb mode: <1550 * DAC clock period(ns) + 10 ns

      Fast (asynchronous) trigger
      AFG mode: < 335 ns (< 385 ns in triggered sweep mode)
      True Arb mode: <1360 * DAC clock period(ns) + 27 ns
      Trigger In to output jitter (rms)
      AFG mode: < 20 ps
      True Arb mode: 0.29*Dac clock period
      Trigger In programmable delay range
      0ps to 2418ps
      Trigger In programmable delay resolution
      78ps
      Maximum Frequency
      AFG: 65 MTps on Rising/Falling Edge, 80 MTps on Both Edges
      True Arb mode: 1/ (Period of the Analog Waveform + 48 DAC Clock period)
      MTps = Mega Transitions per second
      Reference clock input
      Connector type
      SMA on rear panel
      Input impedance
      50 Ω, AC coupled
      Input voltage range
      0.2Vpp to 2Vpp
      Damage level
      Maximum Input voltage: -0.3V to 3.6V
      Maximum input power: 30 dBm (50 Ω)
      Frequency range
      5 MHz to 200 MHz
      Frequency Resolution
      1 Hz
      Reference clock output
      Connector type
      SMA on rear panel
      Output impedance
      50 Ω, AC coupled
      Frequency
      10 MHz TCXO | 100 MHz VCOCXO (Optional)
      Initial accuracy @ 25 °C
      ± 1.0 ppm | ± 500 ppb (Opt.)
      Aging
      ± 1.0 ppm/year | ± 500 ppb/year (Opt.)
      Stability vs. temperature
      ± 1 ppm | ± 50 ppb(Opt.)
      Amplitude
      1.65 Vpp
      Phase Noise @ 20 MHz carrier
      -120 dBc/Hz at 100 Hz ; -140 dBc/Hz at 1KHz;-150 dBc/Hz at 10 KHz
      Phase Noise @ 100 MHz carrier(Opt.)
      -120 dBc/Hz at 100 Hz ; -145 dBc/Hz at 1KHz;-150 dBc/Hz at 10 KHz
      External Clock Input
      Connector type
      SMA on rear panel
      Input impedance
      50 Ω, AC coupled
      Frequency 6
      True Arb:
      SampleRate / N where:
      N = 4, 8, 16, 32 and SampleRate = 3.087÷6.16 GSps
      N = 2, 4, 8, 16, 32 and SampleRate = 3.087÷5.0 GSps

      N = 2, 4, 8, 16 and SampleRate = 1.54÷3.087 GSps
      N = 1, 2, 4, 8, 16 and SampleRate = 1.54÷2.5 GSps

      AFG: 192.5 MHz, 385 MHz, 770 MHz or 1540 MHz
      (selectable)
      Input Power Range
      +0 dBm to +10 dBm
      Damage Level
      15 dBm
      6 When using the External Clock Input the SampleRate must be in the range 3.08÷6.16 GHz for AWG-506X/506XD and must be in the range 1.5÷3 GHz for AWG-503XD, with X = 2,4,8.

      7 For AWG-503xD models the max Sampling rate is limited to 3Gsps
      Sync Clk Out
      Connector type
      SMA on rear panel
      Output impedance
      50 Ω, AC coupled
      Frequency
      AFG Mode:
      6.16Ghz / N where N=16, 32, 64, …, 2048

      True Arb Mode:
      Sampling Rate/N, N=16, 32,,.., 2048 (AWG–506x/506xD)
      2 * Sampling Rate/N, N=16, 32,,.., 2048 (AWG–503xD)
      Amplitude
      1Vpp into 50 Ohm
      External Modulation input
      Connector type
      SMA on rear panel
      Input impedance
      10 KΩ
      Number of inputs
      1
      Bandwidth
      10 MHz with 50 MS/s sampling rate
      Input voltage range
      -1 V to +1 V (except FSK, PSK).
      Vertical resolution
      FSK, PSK: 0V÷3.3V with 1.65V fixed threshold
      12-bit
      Pattern Jump In (optional)
      Connector type
      DSUB15
      Input signals
      DATA[0..7] + Data_Select + Load
      Internal Data Width
      14 bit, multiplexed using Data_Select
      Number of addressable entries
      16384
      Data Rate
      DC to 1 MHz
      Input Range
      VIL = 0V to 0.8V / VIH= 2V to 3.3V
      Impedance
      Internal 1kΩ pull-up resistor to Vcc (3.3V)
      Power
      Source Voltage and Frequency
      100 to 240 VAC ±10% @ 45-66 Hz
      Max. power consumption
      Max. 100W (AWG 5062/5062D/5032D)
      Max. 200W (AWG 5064/5064D/5034D)
      Max. 300W (AWG 5068/5068D/5038D)
      Environmental characteristics
      Temperature (operating)
      +5 °C to +40 °C (+41 °F to 104 °F)
      Temperature (non-operating)
      -20 °C to +60 °C (-4 °F to 140 °F)
      Humidity (operating)
      5% to 80% relative humidity with a maximum wet bulb temperature of 29°C at or below +40°C, (upper limit de–rates to 20.6% relative humidity at +40°C). Noncondensing
      Humidity (non-operating)
      5% to 95% relative humidity with a maximum wet bulb temperature of 40°C at or below +60°C, upper limit de–rates to 29.8% relative humidity at +60°C. Noncondensing.
      Altitude (operating)
      3,000 meters (9,842 feet) maximum at or below 25°C
      Altitude (non-operating)
      12,000 meters (39,370 feet) maximum
      EMC and safetyCE compliant
      Safety
      EN61010-1
      Main Standards
      EN 61326-1:2013 – Electrical equipment for measurement, control and laboratory use – EMC requirements – Part 1: General requirements
      Immunity
      EN 61326-1:2013
      System specifications
      Display
      7 inch, 1024x600, capacitive touch LCD
      Operative System
      Windows 10
      External Dimensions
      W 445 mm – H 135 mm – D 320 mm
      (3U 19” rackmount)
      Weight
      Max. 26.45 lbs (12 Kg)
      Front panel connectors
      CH N OUTPUT (SMA) where N=2,4,8 depending on the model
      MARKER N OUT (SMA) where N=1,2,4 depending on the model
      TRG IN N(SMA) where N =1,2
      2 USB 3.0 ports
      Rear panel connectors
      Ref. Clk. IN (SMA)
      Ref. Clk. Out (SMA)
      Ext. Mod. IN (SMA)
      Sync Clk Out (SMA)
      Ext Clk IN(SMA)
      Sync IN (Infiniband 4X)
      Sync OUT (Infiniband 4X)
      Pattern Jump In (DSUB15) (AWG-5000-FSS opt. only)
      POD X[7..0] where X=A,B,C,D depending on the model
      (Customized Mini SAS HD)
      External Monitor ports (one or more)
      2 USB 2.0 ports or more
      4 USB 3.0 ports
      Ethernet port (10/100/1000BaseT Ethernet, RJ45 port)
      2 PS/2 keyboard and mouse ports
      2 DPI ports
      1 DVI port
      Hard Disk
      1 TB SSD or better
      Processor
      Intel® Pentium 3.7 GHz (or better)
      Processor Memory
      32 GB or better