General Overview High-Speed Digitizer 8-4 channels, 12-bit, 1.6-3.2 GS/s October 22, 2015 Jean-Luc Lehmann Product Manager Etienne Beguin Marcom Specialist
High-Speed Digitizer Technology Expertise Our technology can enhance the products you re creating on the following aspects: Better measurement fidelity and signal integrity Higher measurement throughput Lower Total Cost of Ownership Reduced footprint Our solution is designed to include in the final purchasing price, those hidden costs that are usually overlooked. Discover what you couldn t see before As fast as technology can take you Pushing the limits of processing speed At the end of your product life cycle, you will save significant amount of time using Keysight high-speed digitizers. Full cost control through life time Reduce the risks today and tomorrow 2
Different Form Factors for Different Applications PCI/PCIe: OEM 1-2 channels and Universities studies PXI/PXIe: Manufacturing test and ATE AXIe: Multichannel system in Physics and beyond 3
Technology Evolution PCI PCIe PXI PXIe cpci VME AXIe 4
State-of-the-Art Modular Digitizer Technology ADC 8- to 16-bit, 100 MS/s to 10 GS/s 5
M9703A Application Focus Areas M9703A Advanced applied physics experiments Hydrodynamics Fusion uw/rf Astronomy M9703A with DDC Option Multi-channel measurements Antenna array calibration (Radar) Radar system prototyping & emulation Multi-band satellite monitoring Passive radar receiver Multi-channel advanced communication (BBIQ, MIMO) 6
Keysight High-Speed Digitizer FASTEST test time! Widest bandwidth, high flexibility and dynamic range on multiple phase-coherent channels, accelerating measurements of large scale active antennas Key Features 12 bit Resolution 8 channels @ 1.6 GS/s Interleaving option to get 4 ch @ 3.2 GS/s DC to 2 GHz input frequency range Real-time flexible wideband digital downconversion (DDC) on 40 phasecoherent channels Up to 1 GS/ch memory > 800 MB/s data transfer Keysight 89600 Software support M9703A OS support Windows XP (32-bit) 7 (32/64-bit) Linux Drivers MD1 software IVI-C, IVI-COM LabVIEW Matlab (through IVI-COM) OTS application software MD1 soft front panel AcqirisMAQS U1092A-S01/S02/S03 89600 VSA software 7
M9703A Features and Benefits Product Features Your Benefits 12-bit resolution up to 3.2 GS/s 8 channels in a single-slot AXIe module PCIe x4 Gen2 back-plane connectivity High dynamic range for the best measurement fidelity Measure the fastest signals Highest channel density to easily build high number of synchronous acquisition channels Highest measurement throughput 8
Digital Down-conversion (DDC) What is a digital down-converter? Real-time digital downconversion (DDC) It s a flexible processing block that allows an ADC to run at full rate while the output sample rate and bandwidth are optimized to match the signal under test. Digital signal processing Produces complex I&Q samples from real ADC samples Frequency translation (tune) Filter and decimation (zoom) 9
M9703A With DDC Option Details Main Functions: DDC on up to 40 phase-coherent channels (1.6 GS/s) Decimation factor by 4 then programmable by 2 n, leading to Sample Rate ranging from 400MS/s down to 200MS/2 N, N=0..18 Fine IF tuning (0.01Hz) over the full digitizer bandwidth (independent per channel) Channel Magnitude Trigger x40 Full Sample Rate (1.6 GSa/sec) Frequency Shift Decimation Filter 10
M9703A With DDC Option Details Interest for your application: Reduce the bandwidth and the sample rate to the appropriate values for the signal being analyzed. Setting the analysis bandwidth around the signal of interest, by shifting the center frequency Triggering on the signal of interest at a specified frequency and bandwidth Noise and other signals in the full ADC bandwidth are eliminated by the DDC, isolating the signal of interest, and increasing the dynamic range in the time-domain waveform through reduced total noise power. 11
Real-Time DDC Decimation Steps Analysis Bandwidth / Frequency span -DDC option Sample Rate with SR2 (SR1) -LDC option Sample Rate with SR2 (SR1) 800 MHz (500 MHz)* 1.6 GS/s (1 GS/s)* N.A. 300 MHz (180 MHz) 400 MS/s (250 MS/s) N.A. 160 MHz (100 MHz) 200 MS/s (125 MS/s) 200 MS/s (125 MS/s) 80 MHz (50 MHz) 100 MS/s (62.5 MS/s) 100 MS/s (62.5 MS/s) 40 MHz (25 MHz) 50 MS/s (31.25 MS/s) 50 MS/s (31.25 MS/s) 160/2 N MHz (100/2 N MHz) 200/2 N** MS/s (125/2 N MS/s) 200/2 N** Ms/s (125/2 N MS/s) *No decimation (real/un-modulated data) 12
OS Systems, Drivers and Software A Modular Software Structure OS support: Frequency Domain Time Domain Windows: XP (32-bit), MathWorks MATLAB 7 (32/64-bit) Linux Keysight 89600 VSA Keysight AcqirisMAQS High-Speed Digitizers Software Front Panel Visual Studio LabWindows CVI LabVIEW VEE MATLAB Instrument Drivers Command Expert C#, C/C++ VB.NET z Automation Platform 13
Questions and Answers
AXIe Section
AXIe: What and Why AdvancedTCA (ATCA) Extensions for Instrumentation and Test What is it? AXIe is a next-generation open standard based on AdvancedTCA with extensions for instrumentation and test, that delivers high performance instrumentation for aerospace defense, high energy physics, semiconductor test and other industries. This standard is governed by the AXIe Consortium, a group of leading organizations in the test and measurement industry and is designed to provide users with popular PC interfaces such as TCP/IP and PCI Express to modular configuration slots which provide resources for advanced instrumentation (www.axiestandard.org). AXIe Consortium, Inc Members: 16
AXIe Standard: What and Why Why another modular test standard? Higher performance per rack inch Greater scalability Integrates easily with PXI/cPCI, LXI and IVI More modularity, more flexibility, higher speeds addresses and range of platforms - ATE Systems, rack-and-stack modular, bench top, module plug-ins Significant reduction of development and unit costs Uses the PCIe data bus standard 17
AXIe Leverages ATCA AXIe AdvancedTCA specific extensions IPMI and resource management Timing and Sync Zone 3 configurations AdvancedTCA draws from and works with existing instrument standards PXI/cPCI/PCIe IVI LXI Virtual PXIe instruments PCIe communication Standard drivers work in all Application Development Environments VISA standard Virtual LXI instruments LAN communication 18
AdvancedTCA as a Foundation AdvancedTCA PICMG 3.0 Standard: proven open system architecture Large board size Ideal for high performance instrumentation Board size matches that of planar instrument design Rack space efficiency Horizontal and vertical configurations Scalability 1 slot to 14 slots, 1 chassis to many Ideal for high power applications Single rail power management and robust cooling Robust system management Intelligent Platform Management Interface (IPMI) enables both single chassis and multi-chassis system control functions 19
AXIe: What and Why AdvancedTCA (ATCA) Extensions for Instrumentation and Test What advantages does it bring? Big brother to cpci/pxi. Same PCIe fabric and programming, but with: Horizontal configurations for minimal rack space, vertical for large systems Larger boards for highest rack and power densities per rack inch High speed trigger, timing, and local bus Integrates easily with cpci/pxi, LXI and IVI ATCA compatibility Longevity PXI 2-slot configuration 5-slot configuration cpci 20
Mechanical Architecture AXIe Blade structure 4 single-size Front End Mezzanines 1 Timebase Mezzanine Front Panel I/O [Common] 1 External Clock Input (SMA) 3 External Trigger (MCX) 2 General Purpose PIO (MMCX) FPGA JTAG Interface for FDK ATCA Blue LED + Backplane FPGA LED 2 x SFP Transceivers (LC Duplex) (*) 4 x DPU FPGA LED Front Panel I/O [M9703A] Mezzanine I/O: 1 Ext Direct Clock (SMA) 2 Channel Signal Input (SMA) 21
M9703A with Wideband, Multichannel Real-Time DDC Digitizer component for Active Antenna test solutions
Challenges for Active Antenna Calibration & Test Are you concerned by the following challenges? 1. Need measurement flexibility with the best sensitivity Measure wideband and complex signals with high resolution Trade-off between different analysis bandwidth and sensitivity Not limited to CW measurements 2. Need to accelerate the measurement time High number of elements (Tx/Rx) to be measured Lots of test conditions and fast changes Measure signal parameters while changing test conditions 3. Need more synchronous acquisition channels in a limited space More elements to be measured in parallel Limited place and/or power Precise angular and amplitude measurements between lots of channels 23
Keysight Solution: M9703A 12-bit Digitizer with Digital Downconversion (DDC) option From days to HOURS! Most flexible measurements with high resolution Fastest measurements Highest number of phase-coherent channels 24
Historical Phased Array Test Challenges Aligning Radiating Elements for Optimum Performance Phase and amplitude errors lead to an increase in side lobe levels (SLL) Large side lobes indicate a waste of beam forming power and cause interference Average side lobe level due to phase and amplitude errors (normalized to isotropic level and using λ/2 element spacing) [1]: Where is the phase error variance (radians) and is the fractional amplitude error variance SLL -3dB HP BW [1]: J. Ruze, Pattern degradation of space fed phased arrays, MIT Lincoln Laboratory, Project Rept. SBR-1, Dec. 1979. 25
Growing Challenges in Phased Array Antenna Array Element Counts Increasing (need speed without loss of accuracy) Digital Moving Closer to the Antenna (may not have access to stimulus in analog form) Broadband Modulated Signals (not just pulsed) (need to generate and capture full-bandwidth signals) Multi-Function (need flexible measurement system, other types of signal analysis such as modulation accuracy) - Search, SAR, etc. - Communications 26
Measuring Relative Phase and Gain Two Approaches Narrow Band Approach - Swept or stepped tone - Narrowband receiver - Measure one freq at a time - Cross-channel computations in time domain - Lower variance by integrating longer (narrower RBW) Broadband Approach - Broadband stimulus - Wideband receiver - Measure all frequencies simultaneously - Compute cross-channel spectrum - Lower variance by averaging Signal Generator AWG DUT RX + DIGITIZER Network Analyzers are limited to narrowband measurements Digitizers and VSA s with DDC s have adjustable bandwidths 27
M9703A With DDC Option Testing up to 40 Phase Coherent Wideband Receiver Channels Multi-Channel support: Single and Paralell 16 channel configuration Frequency range: 10 MHz to 50 GHz Analysis BW 1 GHz (interleaved) 800 MHz 300 MHz (DDC) Phase coherency 75 fs rms 0.03 @ 400 MHz BB 28
AXIe M9703A Digitizer with DDC Feature Value #1: FLEXIBILITY Measure various type of signals with optimized resolution We can help you: Measure the wideband signals with the best sensitivity Measure complex signals Change measurement conditions and measure the signal of interest M9703A with DDC Traditional solution Sinusoid Pulse signal Dual-tone Multi-tone (> 2) Live signal Beam forming Complex stimulus/response 29
AXIe M9703A Digitizer with DDC Feature Value #2: SPEED of MEASUREMENT We can help you: Accelerate the data upload time Reduce the data post processing workload Measure only the signals of interest Increase the number of measurements in a given time Decimated Sample Rate Analysis Bandwidth 400 MS/s* 300 MHz* 200 MS/s 160 MHz 100 MS/s 80 MHz 50 MS/s 40 MHz 200/2 N** MS/s 160/2 N** MHz *Fs/4 filter has full tuning resolution, but has limited aliasing protection for signals wider than 400 MHz. ** N is an integer, which value is any number between 0 and 18. 30
AXIe M9703A Digitizer with DDC Feature Value #3: Scalability Build the highest number of acquisition channels We can help you: Easily scale-up acquisition channels Reduce the size of your measurement instrumentation Reduce the power consumption of your system Up to 16 simultaneous channels in 2U Up to 40 simultaneous channels in 4U 2U 4U 31
M9703A Wideband Digital Receiver/Digitizer for Passive Radar 32
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Recent Resurgence in Passive Radar Interest The principle of passive radar has been known for a long time - See without being seen : use third-party transmitters in the environment such as radio and television stations to detect objects, instead of own transmitter - Technique known since 1930 s Recent progress in ADC and real-time signal processing technology allow cheaper radar systems, lead to a resurgence of interest in passive radar technology - Wideband and high resolution ADC for a fully digital receiver - Powerful FPGAs for real-time data processing on a variety of broadcast signals The ability to monitor multiple emitters at the same time independent measurements of bi-static range and significant detection improvement - 2 antennas 2D radar - 4 antennas 3D radar 34
Typical Illuminators Usually in the VHF, UHF & SHF bands: 30 MHz to 3 GHz Analog television signals FM radio signals in VHF Mobile phone base stations (GSM, WCDMA, LTE, ) Digital audio broadcasting (DAB, DAB+, T-DMB, ) Digital video broadcasting (DVB-T, ) GPS satellites 35
Passive Radar Manufacturer Challenges Reduce overall costs - Reduce system complexity, e.g. by minimizing RF analog front-end - Use integrated COTS HW components and focalize on final system integration An. BF Sig. Cond. Few antennas (up to 4 typ) An. BF Sig. Cond. An. BF Sig. Cond. An. BF Sig. Cond. Improve radar performance - Better detection accuracy - Increase detection range Increase system scalability and flexibility - Reference design for different needs - Better channel density - Multiple bi-static range measurements in parallel Towards a fully digital receiver ADC ADC ADC ADC Data processing and control Scalable # of antennas (4, 8, 16, 24, 32 typ) ADC, Digital beam former and data pre-processing Data processing and control 36
Solving Challenges for Passive Radar 1. Need to reduce costs Simplify receiver architecture/get towards a digital receiver Faster system integration Easier scalability Faster and easier upgradability to new technology 2. Need to improve performance Detect reflected signals in the range of 70 to >100 db lower than direct signals Monitor multiple emitters in parallel Measure independently and with flexibility Improve phase tracking & synchronization 3. Need more phase-coherent channels Connection to a higher number of antennas Limited space and/or power in a mobile or fix radar station 1. Most flexible digitizer technology DC to 1 GHz BW: Capture the full spectrum with a single digitizer component 4x FPGAs: Powerful real-time data processing AXIe platform: Common modular digitizer architecture 8 to 40 coherent channels in 4U height 2. Optimized performance measurements Flexible real-time down conversion for best dynamic range Scalable 8 to 40 parallel receivers Incorporate reference channels for real-time alignment 3. Most compact test systems 8 channels in a 1-slot card Up to 40 channels in just 4U rack space 161 W consumption for 8 channels 37
Keysight M9703A Wideband Digital Receiver/ Digitizer Direct Digitization of signals with optimized dynamic range on up to 40 phase-coherent channels! Key Features 8 channels @ 1.6 GS/s (4 ch @ 3.2 GS/s when interleaved) Up to 40 phase-coherent channels in a 4U chassis DC to 2 GHz input frequency range 1 khz to 300 MHz analysis bandwidth with Real-time digital down conversion (DDC) for best sensitivity 12 bit resolution > 800 MB/s data transfer Keysight 89600 VSA Software support M9703A OS support Windows XP (32-bit) 7 (32/64-bit) Linux Drivers MD1 software IVI-C, IVI-COM LabVIEW Matlab (through IVI-COM) OTS application software MD1 soft front panel AcqirisMAQS U1092A-S01/S02/S03 89600 VSA software 38
M9703A DDC for 8 to 40 Coherent Channels x8 to x40 Full Sample Rate (1.6 GSa/sec) Frequency Shift Decimation Filter Reduce and tune the analysis bandwidth to match the signal of interest - Reduced noise (including quantization noise) and interference Optimized sensitivity - Allows lower sample rate without aliasing Excellent measurement accuracy Set the sample rate to match the signal being analyzed - More efficient use of memory Longer duration captures - Less data to transfer for the same duration Faster data transfer and measurement Set complex signal (IQ) magnitude trigger level - Magnitude at specified LO and bandwidth Trigger on the signal of interest - Hysteresis level control to avoid triggering on noise No erroneous acquisition 39
Noise Power Spectral Density Reaches Close to 16-bit Performance NSD with no signal at input, 10 MHz span @ 850 MHz 40
EVM performance / dynamic range GSM signal @ 900 MHz and 1.8 GHz 41
EVM performance / dynamic range DVB-T signal @ 850 MHz with 10 MHz band 42
Dynamic range / noise level 900 MHz CW signal and 30 MHz span 43
Dynamic range / noise level 900 MHz CW signal and 80 MHz span 44
Dynamic range / noise level 1.8 GHz CW signal and 80 MHz span 45
Dynamic range / noise level 850 MHz CW signal and 10 MHz span 46
Observed M9703A SFDR (1VFSR) 400 MHz Bandwidth SFDR 625 MHz -83.11 dbc 400 MHz -86.67 dbc 100 MHz -92.23 dbc 47
Dynamic range / noise level No Filters on Input Signal Conditions SFDR Noise floor 900 MHz CW signal (-10dBm) and 30 MHz span -92 dbc -105 dbc 900 MHz CW signal (-10 dbm) and 80 MHz span -90 dbc -100 dbc 1.8 GHz CW signal (-10 dbm, undersampled at 1.6GHz) and 80 MHz span -82 dbc -97 dbc 850 MHz CW signal (-10 dbm) and 10 MHz span -92 dbc -110 dbc 48
M9703A High-Speed, High-Resolution Multichannel Digitizer High Speed Digitizer for Capture/Playback and Radar Emulation
Capture / Playback Solution M9703A Wideband digital receiver/digitizer M8190A Arbitrary Waveform Generator World Class Digitizer Features: 12 bit Resolution 8 channels up to 1.6 GS/s - 4 channels up to 3.2 GS/s Real-time flexible DDC on up to 40 phase-coherent channels DC to 2 GHz input frequency range SFDR: -83 dbc nominal (625 MHz BW @ fin = 400 MHz) Up to 1 GS/ch memory Segmented memory mode > 800 MB/s data transfer speed Precision AWG with DAC resolution of: 14 bit up to 8 GS/s 12 bit up to 12 GS/s Up to 2 GSamples Arbitrary Waveform Memory per channel Up to 5 GHz analog bandwidth per channel 3 selectable output paths: direct DAC, DC and AC SFDR: -80 dbc typ. (fout = 100 MHz, Fs = 7.2 GHz, 14-bit mode) Harmonic distortion: -72 dbc typ. (fout = 100 MHz, Fs = 7.2 GHz) Advanced sequencing scenarios define stepping, looping, and conditional jumps of waveforms or waveform sequences 2 markers per channel (does not reduce DAC resolution) 50
Multi-Channel Capture/Playback Down- Converter Down- Converter M9703A Multi-Channel Digitizer Add Radar Emitters M8190A Multi- Channel AWG(s) Upconverter/ Vector Sig. Gen. Upconverter/ Vector Sig. Gen. Add Comms Emitters Add Other Emitters Capture Live Signals Add Emitters Playback Multi-Emitter Test Signals 51
Capture Two X-Band Signals with PXAs and M9703A Multi-Channel Digitizer X-Band Input into Both PXAs CH1 Recording: LFM chirped radar at 10.1 GHz CH2 Recording: Barker radar at 9.8 GHz 52
M9703A High-Speed, High-Resolution Multichannel Digitizer High Speed Digitizer for large-scale advanced physics experiments
Solving Challenges For Large-Scale Physics Need to easily build large number of synchronous channels providing faster measurements with the best fidelity 1. Need to improve measurement fidelity Need more dynamic range Need to detect lower level signals 1. Measure with the best fidelity at this speed 60 dbc SFDR typically @ 410 MHz 58 db SNR typically @ 410 MHz 8.8 Effective bits typically @ 410 MHz 2. Need high speed channels Need to see both edge and shape very and short signals Need to transfer data as fast as possible 2. Highest speed DC-coupled 12 bit digitizer Get up to 3.2 GS/s sampling rate 650 MB/s sustained data transfer through backplane PCIe link 3. Need high number of synchronous channels Large number of channels in a limited space and power Need high-number of synchronous channels 3. Most compact test systems 8 channels in a 1-slot card 161 W consumption for 8 channels Build 80 channels in just 8U rack space Multi-board synchronization 54
AXIe M9703A Digitizer Measure Fast Signals with the Best Accuracy We can help you: Measure fast signals with the better accuracy Detect lower level signals Instrument ENOB (typ) @ 410 MHz SNR (typ) @ 410 MHz M9703A 8.9 (9.1 with FRF option) 56 db (58 with FRF option) Vendor X product A < 6.4 < 41.3 db Vendor X product B Not enough bandwidth Not enough bandwidth 55
AXIe M9703A Digitizer Measure the Fastest Signals with a DC-coupled 12-bit Accuracy We can help you: Measure very fast signals with the best accuracy Accelerate the data upload time Instrument Maximum sampling rate Analog bandwidth M9703A 3.2 GS/s DC to 1 GHz Vendor X product A 1 GS/s DC to 250 MHz Vendor Y 200 MS/a DC to 150 MHz 12-bit resolution DC-coupled digitizers speed 56
AXIe M9703A Digitizer Build the Most Compact Acquisition Systems We can help you: Reduce the size of your measurement instrumentation Lower the power consumption of your measurement system Increase the number of acquisition channels of your system How to build an > 80-channel acquisition system @ > 1 GS/s Up to 80 channels (10bit) Up to 64 channels (8bit) Up to 32 channels (12bit) Up to 96 channels (12bit) Up to 80 channels (10bit) Up to 64 channels (8bit) Up to 32 channels (12bit) Up to 80 channels (12bit) 9U 12U 8U Max number of channels in 10U rack-mount space Max number of channels in 9U rack-mount space 57
Target Applications Summary Features, Benefits and Applications Particle Physics µw/rf Astronomy Tokamak (Fusion) Inertial confinement (Fusion) Hydrodynamics X-Ray imaging Product Features 12-bit resolution Up to 3.2 GS/s 8 channels in a single-slot AXIe module PCIe x4 Gen2 back-plane connectivity Your Benefits High dynamic range for the best measurement fidelity Measure the fastest signals Highest channel density to easily build high number of synchronous acquisition channels Highest measurement throughput 58
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