Keysight SystemVue 2020 Update 1 | 2.5 Gb
The PathWave development team is pleased to announce the availability of SystemVue 2020 Update 1. This update Includes updates to 5G NR, Spectrasys and RF link, phased array enhancements for Radar and EW applications, plus a new 802.11ax receiver. The Radar/EW library includes new example structure, updates to current examples and new reference examples.
Keysight has announced the release of its updated PathWave * Design 2020 software suite. The new suite includes updates to the electronic design automation software to accelerate design workflows for radio frequency (RF) and microwave, 5G, and automotive design engineers. The new releases of flagship products included in the software suite are: PathWave Advanced Design System (ADS) 2020, PathWave RFIC Design (GoldenGate) 2020, PathWave System Design (SystemVue) 2020, and PathWave RF Synthesis (Genesys) 2020.
The PathWave * Design 2020 software suite accelerates product development by reducing the time engineers spend in the design and simulation phase. Its libraries and customized simulators reduce setup time and automation improvements reduce manual work. The software seamlessly integrates circuit design, electromagnetic (EM) simulation, layout capabilities, and system level modeling, reducing time needed for importing and exporting designs and fixing errors associated with changing tools. Improvements in data analytics allow for rapid analysis and timely design decisions.
PathWave System Design (SystemVue) 2020 Update 1.0 Release Notes
Data Flow Analysis/Models
- Added new parameter to ReadSignalStudioFile to allow the user to playback the normalized or unnormalized file (this only applies to files generated by SystemVue or ADS).
- Added support for overlapped subarrays in models BeamformerWeights, Splitter_M, and Combiner_M, which allow one element to be used by multiple subarrays. It enables the generation of multiple beams in a single simulation.
- AntennaArrayTx/AntennaArrayRx models can now specify polarization using Etheta/Ephi, LHC/LHC, or Ellipse Axial Ratio and Tilt Angle when Element Pattern Type is set to Isotropic, Three Sector Antenna for Y-Z URA, or Cosine Antenna.
- AntennaArrayTx model can now decompose far-field envelope signal (Output port) into any one of the polarization pattern component pairs Etheta/Ephi, Eleft/Eright, Eco/Ecross, Ludwig 2 (Az/El), Ludwig 2 (Al/Ep), Ludwig 3 (H/V) (Polarization1Output/Polarization2Output ports).
- AntennaArrayRx model now takes into account Element Pattern Polarization when computing output envelope matrix signal but still assumes each element is perfectly matched (in polarization sense) to the incoming signal.
Phased Array Analysis
- Made complex polarization patterns available in the dataset of Phased Array Analysis (see variables ArrayMeas_Polarization1_ComplexPattern and ArrayMeas_Polarization2_ComplexPattern). Previously, only their magnitude was available in the dataset (see variables ArrayMeas_Polarization1_Pattern and ArrayMeas_Polarization2_Pattern).
- Added support for easy creation of Beam Pattern UV Plot graphs and Beam Pattern Cut (Theta/Phi/U/V) graphs (see Easy Graph Plotting of Beam Patterns).
RF_Link Simulation
- Delay introduced in each path (due to filter transients) is now available in the dataset with the extracted behavioral data (see variables PathDelay and PathDelayInSamples).
- Added support for the VarAmp and ATTN_Ctrl models (see example Examples\RF Architecture Design\VarAmpAGC_RF_Link.wsv).
Baseband_Link
- Renamed Baseband_Link part and Baseband_Link, Baseband_LinkCx, Baseband_LinkEnv models to Baseband_Link, Baseband_Link, Baseband_LinkCx, Baseband_LinkEnv respectively.
- Added new examples to demonstrate different use cases of Baseband_Link:
. 5G NR Downlink TX example (Examples\Tutorials\Algorithm_Design\Baseband_Link\3GPP_NR folder)
. Radar RF modeling examples (Examples\Tutorials\Algorithm_Design\Baseband_Link\Radar folder)
System Analysis/Models
- The Frequency Comb source now supports phase noise.
Platform
- Added support for setting axis' range and units for 3D Graph.
- A new improved error window allows the filtering of messages based on type (Error/Warning/Message) as well as associated workspace item type (Analysis/Design/Equation/etc.) (see Error Log).
- The Parameter Synchronization Tool enables easy comparison and synchronization of the matching model or design parameters. Both parts and design parameters can be synchronized. Either (1) select one or more parts on a schematic, right-click, and select "Sync Part Parameters…" or (2) select one or more designs in the workspace tree, right-click, and select "Sync Design Parameters…".
- New 3D graph visualization palettes, including standardized ones like: inferno, viridis, and cividis.
- New graph color themes, including dark, light, and PathWave palettes, which are found in Tools > Options > Graph.
5G Advanced Modem Library
- All features conform to V15.4.0
- New functions
. Downlink
.. Supported NR DownLink frame synchronization method using CP+DMRS.
.. Supported user-defined Bandwidth setup in NR Downlink source and receiver.
.. Supported VSA setup file generation for MIMO configuration.
. Uplink
.. Supported user-defined Bandwidth setup in NR Uplink source and receiver.
- EVM function update (NR_DL_EVM and NR_UL_EVM)
. Supported user-defined Bandwidth setup.
. Updated NR DownLink EVM model to support MIMO measurements.
. Updated NR EVM model to support composite Magnitude and Phase error measurements.
. Updated NR EVM model to support EVM Window and Symbol Timing setup.
- Test Models update
. Updated NR DownLink Test Model example (NR_DL_TM.wsv) to support the latest Test Model defined in 38.141-1 / 38.141-2 of version V16.1.0 (2019-09).
WLAN 802.11ax Library
- All features of 802.11ax library comply with 802.11ax PHY in the IEEE P802.11ax/D1.2, April 2017 specification.
- Added new 802.11ax receiver subnet WLAN_11ax_Receiver. It can demodulate 802.11ax waveform to get the outputs of Constellation, Channel coded bits and MPDU bits.
- Supported 80+80MHz bandwidth in 802.11ax source and EVM model.
- Added the CombineEqualizerUsingLLTF, CompensateSamplingClockError, RemoveEqualizerPhaseRamp, ActiveAntennaThreshold, TrackingMode, EqualizerSmoothing, and EqualizerSmoothingLength parameters for WLAN_11ax_EVM model to be consistent with VSA 89600.
- Added two new examples for 802.11ax BER and FER simulation:
. Examples\Baseband Verification\WLAN\WLAN_11ax\WLAN_11ax_Rx_AWGN.wsv
. Examples\Baseband Verification\WLAN\WLAN_11ax\WLAN_11ax_Rx_Fading.wsv
- Added three new examples for 802.11ax VTB simulation.
. Examples\VTB\WLAN_11ax\Tx\WLAN_802.11ax_Source.wsv
. Examples\VTB\WLAN_11ax\Tx\WLAN_802.11ax_Tx.wsv
. Examples\VTB\WLAN_11ax\Rx\WLAN_802.11ax_ReferenceSensitivity.wsv
Radar Baseband Verification Library
Example and Folder reorganizations:
<Electronic Warfare>
- Proposed globally accepted EW classifications (ES, EA and EP) from reference textbooks.
- Renamed existing EW examples with the newly proposed EW classifications.
- ES_ChannelizedTx/Rx are combined as one example.
- ES_DOA angle measurement examples are combined and updated for usability.
<Environment Modeling>
<Obsolete Examples>
- Contains old examples that R&D will cease to support after 2020U1 release.
<PhasedArray Performance Modeling>
- Radar_PhasedArray_DataFlow.wsv
. Demonstrates phased array RF impairment modeling using DataFlow simplified amplitude and phase shifting.
. Radar_PhasedArray_SpectraSysRFLink.wsv
. Demonstrates phased array RF impairment modeling using Phased Array RF_Link and Spectrasys phased array RF models.
. Customized RF impairment modeling using ADAR1000 frequency-dependent chipset model is available for user evaluation.
- ADBF (Adaptive Rx Beam Forming) Example updated for improved usability.
<Radar System Design>
- Updated AntennaTx/Rx based pattern plotting example and scanning example.
. AntennaTRx_BasicTest.wsv
. AntennaTRx_Scan_Modes.wsv
- Established new Monopulse Phased Array Radar Tracking And Scan Example Workspace (PhaseArrayRadar_TAS.wsv):
. Realized monopulse phased array radar scanning with predefined beam grids.
. Realized simplified radar target tracking workflows for multiple moving targets.
. Dynamic display of the workspace include
.. Antenna scan and target detection confirming with beam grids
.. Phased array antenna beam patterns
.. Target tracking trajectories plotting
<Signal and Data Processing>
<Signal Generation>
- Moved the "AmbiguityFunction" example folder into this folder.
- Established the "Phase_Coding_Signal.wsv" example which shows how to generate the phase coded signals, including Barker code, PRN code, ChirpLike code (Frank Code, P1 to P4 and Px Code) and PolyTime (T1(n), T2(n), T3(n), T4(n)) example folders. Also enhanced parameter setting and example note.
- Modified the "CW_Signal.wsv" example with parameter setting and example note enhancements. Single-frequency CW signal generation case is added.
<TR Module Modeling>
- Radar_RF_Modeling_SingleTRx.wsv
. Presents a simplified single channel Tx and Rx RF impairment modeling.
The original examples and the new ones added for 2020U1 are all reorganized inside these folders. The help documentation is also updated for this change.
Multiple Ray Tracing for Automotive Radar Complex Scenario Analysis
- Enabled "Phase Center" checkbox in antenna array pattern import tab to enable the user to include element spacing incurred phase shifts in antenna patterns.
Documentation
- Reorganized and consolidated all Sys-Parameter related documentation section under the Using SystemVue > Sys-Parameters section.
- Added new parameter to ReadSignalStudioFile to allow the user to playback the normalized or unnormalized file (this only applies to files generated by SystemVue or ADS).
- Added support for overlapped subarrays in models BeamformerWeights, Splitter_M, and Combiner_M, which allow one element to be used by multiple subarrays. It enables the generation of multiple beams in a single simulation.
- AntennaArrayTx/AntennaArrayRx models can now specify polarization using Etheta/Ephi, LHC/LHC, or Ellipse Axial Ratio and Tilt Angle when Element Pattern Type is set to Isotropic, Three Sector Antenna for Y-Z URA, or Cosine Antenna.
- AntennaArrayTx model can now decompose far-field envelope signal (Output port) into any one of the polarization pattern component pairs Etheta/Ephi, Eleft/Eright, Eco/Ecross, Ludwig 2 (Az/El), Ludwig 2 (Al/Ep), Ludwig 3 (H/V) (Polarization1Output/Polarization2Output ports).
- AntennaArrayRx model now takes into account Element Pattern Polarization when computing output envelope matrix signal but still assumes each element is perfectly matched (in polarization sense) to the incoming signal.
Phased Array Analysis
- Made complex polarization patterns available in the dataset of Phased Array Analysis (see variables ArrayMeas_Polarization1_ComplexPattern and ArrayMeas_Polarization2_ComplexPattern). Previously, only their magnitude was available in the dataset (see variables ArrayMeas_Polarization1_Pattern and ArrayMeas_Polarization2_Pattern).
- Added support for easy creation of Beam Pattern UV Plot graphs and Beam Pattern Cut (Theta/Phi/U/V) graphs (see Easy Graph Plotting of Beam Patterns).
RF_Link Simulation
- Delay introduced in each path (due to filter transients) is now available in the dataset with the extracted behavioral data (see variables PathDelay and PathDelayInSamples).
- Added support for the VarAmp and ATTN_Ctrl models (see example Examples\RF Architecture Design\VarAmpAGC_RF_Link.wsv).
Baseband_Link
- Renamed Baseband_Link part and Baseband_Link, Baseband_LinkCx, Baseband_LinkEnv models to Baseband_Link, Baseband_Link, Baseband_LinkCx, Baseband_LinkEnv respectively.
- Added new examples to demonstrate different use cases of Baseband_Link:
. 5G NR Downlink TX example (Examples\Tutorials\Algorithm_Design\Baseband_Link\3GPP_NR folder)
. Radar RF modeling examples (Examples\Tutorials\Algorithm_Design\Baseband_Link\Radar folder)
System Analysis/Models
- The Frequency Comb source now supports phase noise.
Platform
- Added support for setting axis' range and units for 3D Graph.
- A new improved error window allows the filtering of messages based on type (Error/Warning/Message) as well as associated workspace item type (Analysis/Design/Equation/etc.) (see Error Log).
- The Parameter Synchronization Tool enables easy comparison and synchronization of the matching model or design parameters. Both parts and design parameters can be synchronized. Either (1) select one or more parts on a schematic, right-click, and select "Sync Part Parameters…" or (2) select one or more designs in the workspace tree, right-click, and select "Sync Design Parameters…".
- New 3D graph visualization palettes, including standardized ones like: inferno, viridis, and cividis.
- New graph color themes, including dark, light, and PathWave palettes, which are found in Tools > Options > Graph.
5G Advanced Modem Library
- All features conform to V15.4.0
- New functions
. Downlink
.. Supported NR DownLink frame synchronization method using CP+DMRS.
.. Supported user-defined Bandwidth setup in NR Downlink source and receiver.
.. Supported VSA setup file generation for MIMO configuration.
. Uplink
.. Supported user-defined Bandwidth setup in NR Uplink source and receiver.
- EVM function update (NR_DL_EVM and NR_UL_EVM)
. Supported user-defined Bandwidth setup.
. Updated NR DownLink EVM model to support MIMO measurements.
. Updated NR EVM model to support composite Magnitude and Phase error measurements.
. Updated NR EVM model to support EVM Window and Symbol Timing setup.
- Test Models update
. Updated NR DownLink Test Model example (NR_DL_TM.wsv) to support the latest Test Model defined in 38.141-1 / 38.141-2 of version V16.1.0 (2019-09).
WLAN 802.11ax Library
- All features of 802.11ax library comply with 802.11ax PHY in the IEEE P802.11ax/D1.2, April 2017 specification.
- Added new 802.11ax receiver subnet WLAN_11ax_Receiver. It can demodulate 802.11ax waveform to get the outputs of Constellation, Channel coded bits and MPDU bits.
- Supported 80+80MHz bandwidth in 802.11ax source and EVM model.
- Added the CombineEqualizerUsingLLTF, CompensateSamplingClockError, RemoveEqualizerPhaseRamp, ActiveAntennaThreshold, TrackingMode, EqualizerSmoothing, and EqualizerSmoothingLength parameters for WLAN_11ax_EVM model to be consistent with VSA 89600.
- Added two new examples for 802.11ax BER and FER simulation:
. Examples\Baseband Verification\WLAN\WLAN_11ax\WLAN_11ax_Rx_AWGN.wsv
. Examples\Baseband Verification\WLAN\WLAN_11ax\WLAN_11ax_Rx_Fading.wsv
- Added three new examples for 802.11ax VTB simulation.
. Examples\VTB\WLAN_11ax\Tx\WLAN_802.11ax_Source.wsv
. Examples\VTB\WLAN_11ax\Tx\WLAN_802.11ax_Tx.wsv
. Examples\VTB\WLAN_11ax\Rx\WLAN_802.11ax_ReferenceSensitivity.wsv
Radar Baseband Verification Library
Example and Folder reorganizations:
<Electronic Warfare>
- Proposed globally accepted EW classifications (ES, EA and EP) from reference textbooks.
- Renamed existing EW examples with the newly proposed EW classifications.
- ES_ChannelizedTx/Rx are combined as one example.
- ES_DOA angle measurement examples are combined and updated for usability.
<Environment Modeling>
<Obsolete Examples>
- Contains old examples that R&D will cease to support after 2020U1 release.
<PhasedArray Performance Modeling>
- Radar_PhasedArray_DataFlow.wsv
. Demonstrates phased array RF impairment modeling using DataFlow simplified amplitude and phase shifting.
. Radar_PhasedArray_SpectraSysRFLink.wsv
. Demonstrates phased array RF impairment modeling using Phased Array RF_Link and Spectrasys phased array RF models.
. Customized RF impairment modeling using ADAR1000 frequency-dependent chipset model is available for user evaluation.
- ADBF (Adaptive Rx Beam Forming) Example updated for improved usability.
<Radar System Design>
- Updated AntennaTx/Rx based pattern plotting example and scanning example.
. AntennaTRx_BasicTest.wsv
. AntennaTRx_Scan_Modes.wsv
- Established new Monopulse Phased Array Radar Tracking And Scan Example Workspace (PhaseArrayRadar_TAS.wsv):
. Realized monopulse phased array radar scanning with predefined beam grids.
. Realized simplified radar target tracking workflows for multiple moving targets.
. Dynamic display of the workspace include
.. Antenna scan and target detection confirming with beam grids
.. Phased array antenna beam patterns
.. Target tracking trajectories plotting
<Signal and Data Processing>
<Signal Generation>
- Moved the "AmbiguityFunction" example folder into this folder.
- Established the "Phase_Coding_Signal.wsv" example which shows how to generate the phase coded signals, including Barker code, PRN code, ChirpLike code (Frank Code, P1 to P4 and Px Code) and PolyTime (T1(n), T2(n), T3(n), T4(n)) example folders. Also enhanced parameter setting and example note.
- Modified the "CW_Signal.wsv" example with parameter setting and example note enhancements. Single-frequency CW signal generation case is added.
<TR Module Modeling>
- Radar_RF_Modeling_SingleTRx.wsv
. Presents a simplified single channel Tx and Rx RF impairment modeling.
The original examples and the new ones added for 2020U1 are all reorganized inside these folders. The help documentation is also updated for this change.
Multiple Ray Tracing for Automotive Radar Complex Scenario Analysis
- Enabled "Phase Center" checkbox in antenna array pattern import tab to enable the user to include element spacing incurred phase shifts in antenna patterns.
Documentation
- Reorganized and consolidated all Sys-Parameter related documentation section under the Using SystemVue > Sys-Parameters section.
Data Flow Analysis/Models
- Fixed issue with AntennaArrayTx model, which ignored E-phi component when pattern files in HFFS, CST format were used.
RF_Link Simulation
- Fixed issue with modeling accuracy of the RF system phase response when the magnitude response was almost flat. This issue was causing incorrect (better than expected) EVM results. This may result in longer delays being introduced in the RF path modeled compared to previous releases.
System Analysis/Models
- Fixed issue with incorrect intermods after mixer and amplifier with a frequency comb as the input signal.
- Fixed issue with IM2 term of f1-f2 not showing up in power spectrum with a frequency comb as the input signal.
- Fixed issue with Multisource part dialog corrupting the descriptions of the individual source signals defined when more than one source signal was added.
- Fixed issue where TIMCP3 measurement with frequency comb input signal did not match TIMCP3 measurement with equivalent multi-carrier input signal.
- Fixed issue with mixer generating a higher than expected DC IM2 component.
Automotive Radar System Design Library
- Fixed issue with gain and Uni/BiDirectional Raster scan output signal inconsistencies for AntennaRx model compared with AntennaTx model (same issue fixed prior to the System Design (SystemVue) 2020 release).
- Fixed issue with Bi/UniRaster Scan false output issues of AntennaPolarizationTx and Rx model as compared with AntennaTx model (same issue fixed prior to System Design (SystemVue) 2020 release).
Radar Baseband Verification Library
- Fixed issue with gain and Uni/BiDirectional Raster scan output signal inconsistencies for AntennaRx model compared with AntennaTx model (same issue fixed prior to System Design (SystemVue) 2020 release).
- Fixed issue with Bi/UniRaster Scan false output issues of AntennaPolarizationTx and Rx model as compared with AntennaTx model (same issue fixed prior to System Design (SystemVue) 2020 release).
Multiple Ray Tracing for Automotive Radar Complex Scenario Analysis
Fixed issue with the amplitude error issue in MRT GUI:
- The AutomotiveRadar_RayTracing_SignalVerification.wsv example is modified accordingly, with Ae_Term (Lamda^2/(4*pi))) additions in all Rx channels (Now both the returned power and standard PEC sphere RCS agrees well with theoretically calculated values). The RayTracing Channel code and .bin file are also updated for the missing sqrt(1/(4*pi)) for this fix.
- The AutomotiveRadar_RayTracing_Demo.wsv example is modified accordingly, with Ae_Term (Lamda^2/(4*pi))) additions in all Rx channels. The .bin files both for the double-car scenario and complex scenario are also updated due to this fix.
- Fixed issue with AntennaArrayTx model, which ignored E-phi component when pattern files in HFFS, CST format were used.
RF_Link Simulation
- Fixed issue with modeling accuracy of the RF system phase response when the magnitude response was almost flat. This issue was causing incorrect (better than expected) EVM results. This may result in longer delays being introduced in the RF path modeled compared to previous releases.
System Analysis/Models
- Fixed issue with incorrect intermods after mixer and amplifier with a frequency comb as the input signal.
- Fixed issue with IM2 term of f1-f2 not showing up in power spectrum with a frequency comb as the input signal.
- Fixed issue with Multisource part dialog corrupting the descriptions of the individual source signals defined when more than one source signal was added.
- Fixed issue where TIMCP3 measurement with frequency comb input signal did not match TIMCP3 measurement with equivalent multi-carrier input signal.
- Fixed issue with mixer generating a higher than expected DC IM2 component.
Automotive Radar System Design Library
- Fixed issue with gain and Uni/BiDirectional Raster scan output signal inconsistencies for AntennaRx model compared with AntennaTx model (same issue fixed prior to the System Design (SystemVue) 2020 release).
- Fixed issue with Bi/UniRaster Scan false output issues of AntennaPolarizationTx and Rx model as compared with AntennaTx model (same issue fixed prior to System Design (SystemVue) 2020 release).
Radar Baseband Verification Library
- Fixed issue with gain and Uni/BiDirectional Raster scan output signal inconsistencies for AntennaRx model compared with AntennaTx model (same issue fixed prior to System Design (SystemVue) 2020 release).
- Fixed issue with Bi/UniRaster Scan false output issues of AntennaPolarizationTx and Rx model as compared with AntennaTx model (same issue fixed prior to System Design (SystemVue) 2020 release).
Multiple Ray Tracing for Automotive Radar Complex Scenario Analysis
Fixed issue with the amplitude error issue in MRT GUI:
- The AutomotiveRadar_RayTracing_SignalVerification.wsv example is modified accordingly, with Ae_Term (Lamda^2/(4*pi))) additions in all Rx channels (Now both the returned power and standard PEC sphere RCS agrees well with theoretically calculated values). The RayTracing Channel code and .bin file are also updated for the missing sqrt(1/(4*pi)) for this fix.
- The AutomotiveRadar_RayTracing_Demo.wsv example is modified accordingly, with Ae_Term (Lamda^2/(4*pi))) additions in all Rx channels. The .bin files both for the double-car scenario and complex scenario are also updated due to this fix.
SystemVue is a focused electronic design automation (EDA) environment for electronic system-level (ESL) design. It enables system architects and algorithm developers to innovate the physical layer (PHY) of wireless and aerospace/defense communications systems and provides unique value to RF, DSP, and FPGA/ASIC implementers. As a dedicated platform for ESL design and signal processing realization, SystemVue replaces general-purpose digital, analog, and math environments. SystemVue "speaks RF", cuts PHY development and verification time in half, and connects to your mainstream EDA flow.
PathWave * System Design (SystemVue) 2020 is a major release. Increasing RF and digital coexistence requires designers to connect their baseband and RF designs earlier in the development cycle. The 2020 release of PathWave System Design is focused on RF System Designers in 5G and Radar applications. This release strengthens our best-in-class RF impairment simulation solution for modern communications and Radar systems.
* The PathWave software platform facilitates a completely new product development culture that creates an environment where design and test engineers can speak the same language. At Keysight, we call this new product development philosophy TestOps.
TestOps empowers you to develop, deploy, analyze, and release new products more accurately and quickly.
In this video we show the Electronic System Level, or ESL, design flow from Keysight based on SystemVue – the fastest way to design and validate challenging physical layer communications systems, where baseband and RF must work together.
Keysight Technologies Inc. is the world's leading electronic measurement company, transforming today's measurement experience through innovations in wireless, modular, and software solutions. With its HP and Agilent legacy, Keysight delivers solutions in wireless communications, aerospace and defense and semiconductor markets with world-class platforms, software and consistent measurement science.
Product: Keysight SystemVue
Version: 2020 Update 1
Supported Architectures: x64
Website Home Page : www.keysight.com
Language: english
System Requirements: PC *
Supported Operating Systems: *
Size: 2.5 Gb
System Requirements
Operating System
Practical Minimums: Windows 7 SP1, 64-bit
Recommended Basic: Windows 10, 64-bit
Recommended 5G, Radar, and Phased Array: Windows 10, 64-bit
CPU
Practical Minimums: Single-core
Recommended Basic: Quad-core and above
Recommended 5G, Radar, and Phased Array: Quad-core and above
Hard disk
Practical Minimums: 10 GB free space
Recommended Basic: 100 GB free space
Recommended 5G, Radar, and Phased Array: 100 GB free space
RAM
Practical Minimums: 4 GB RAM
Recommended Basic: 16 GB RAM and above
Recommended 5G, Radar, and Phased Array: 32 GB RAM and above
Display
Practical Minimums: 1280 x 720
Recommended Basic: 1920 x 1200
Recommended 5G, Radar, and Phased Array: 1920 x 1200
Software Security
Practical Minimums: USB hardware key
Recommended Basic: Wired LAN, or Wireless LAN
Recommended 5G, Radar, and Phased Array: Wired LAN, or Wireless LAN
LAN Connection
Practical Minimums: Not required
Recommended Basic: Recommended
Recommended 5G, Radar, and Phased Array: Recommended
Test Instrument Interface
Practical Minimums: Not required
Recommended Basic: LAN
Recommended 5G, Radar, and Phased Array: LAN
Touch User Interface
Practical Minimums: N/A
Recommended Basic: Not supported
Recommended 5G, Radar, and Phased Array: Not supported
Operating System
Practical Minimums: Windows 7 SP1, 64-bit
Recommended Basic: Windows 10, 64-bit
Recommended 5G, Radar, and Phased Array: Windows 10, 64-bit
CPU
Practical Minimums: Single-core
Recommended Basic: Quad-core and above
Recommended 5G, Radar, and Phased Array: Quad-core and above
Hard disk
Practical Minimums: 10 GB free space
Recommended Basic: 100 GB free space
Recommended 5G, Radar, and Phased Array: 100 GB free space
RAM
Practical Minimums: 4 GB RAM
Recommended Basic: 16 GB RAM and above
Recommended 5G, Radar, and Phased Array: 32 GB RAM and above
Display
Practical Minimums: 1280 x 720
Recommended Basic: 1920 x 1200
Recommended 5G, Radar, and Phased Array: 1920 x 1200
Software Security
Practical Minimums: USB hardware key
Recommended Basic: Wired LAN, or Wireless LAN
Recommended 5G, Radar, and Phased Array: Wired LAN, or Wireless LAN
LAN Connection
Practical Minimums: Not required
Recommended Basic: Recommended
Recommended 5G, Radar, and Phased Array: Recommended
Test Instrument Interface
Practical Minimums: Not required
Recommended Basic: LAN
Recommended 5G, Radar, and Phased Array: LAN
Touch User Interface
Practical Minimums: N/A
Recommended Basic: Not supported
Recommended 5G, Radar, and Phased Array: Not supported
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Added by 3% of the overall size of the archive of information for the restoration
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Added by 3% of the overall size of the archive of information for the restoration
No mirrors please