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Supported Standards: IEEE 802.11p–2012, (ETSI ES 202 663, IEEE 1609.4–2010) Frequency bands: 5.850–5.925 GHz, channels 172, 174, 176, 180, 182, 184 Channel bandwidth: 10 MHz, OFDM Modulation Modes: 3, 4.5, 6, 9, 12, 18, 24, 27 Mbps for 10 MHz BW signal Maximum output power: 5.9 GHz: –10 to +23 dBm (± 2 dBm), 5.9 GHz: IEEE 1609 Class C Minimum sensitivity: –97 dBm @ 3 Mbps Operating temperature range: –25 to +55 °C DetailsThe SEA 9719 cRIO module enables communication according to the IEEE 802.11p standard on the NI CompactRIO™ platform. This standard provides a basis for the future Vehicle-to-Anything (V2X) or Car-to-Anything (C2X) technologies. By means of this module regular IEEE 802.11p messages (PHY & MAC layer) can be transmitted and received from within LabVIEW™ user applications. For easy integration a LabVIEW driver with a full set of API functions is available to the developer. The module is connected to a computer system (typically a NI CompactRIO) via Ethernet and the user application runs on the Real-Time controller. No LabVIEW FPGA programming is required. Optionally the module can be operated without an NI CompactRIO Controller (stand alone), by connecting it directly to a PC via Ethernet and running the user application on the PC. The required power of 7 to 30 VDC can be supplied through an adequate cable (see accessory below) from the same power source as the NI CompactRIO system.Delivery Scope1 * SEA 9719 802.11p Communication Module1 * Printed Hardware Manual operation instructions, safety instructions and specifications AccessoryGPS option (66000043) is separately available NotesFor programming and operation a LabVIEW Development Environment 2017 or higher is required (see tab Product FAQ).The software is available as a download.CompactRIO Products Home

Optional function for the SEA 9719 module. Disciplines the internal MAC clock. Is also compatible with GPS simulators.DetailsThe GPS Option for SEA 9719 cRIO module enables the GPS receiver as time source for timestamping the data packets by disciplining the internal MAC clock. Requires additionally a SEA 9719  802.11p Communication Module w/ GPS antenna.

Measure RF signals and validate and check for standard compliance all in parallel! Apply typical RF measurement and analysis methods. Validate conformity of RF signals to international standards. Combine traceable (calibrated) measurements with the NI PXI VST hardware. Use the same device for parallel 802.11p communication, manipulation, and measurement.DetailsThe 802.11p Add-On for LabVIEW - RF-COMPLIANCE delivers unique access to the DSRC 802.11p standard in LabVIEW™ for the future V2X (Vehicle-To-Anything) communications based on NI™ hardware platforms USRP and VST (PXI). It includes (a) a LabVIEW API (functions palette) incl. examples for programming 802.11p-based applications in LabVIEW and (b) the Host Control Manager (HCM) for interaction with the local communication hardware.The RF-COMPLIANCE package enables transmission (send + receive) of regular 802.11p packets (MAC + PHY layer) and offers precise timing of the MPDU-packet output as well as precise time information of the received packets. In addition, the RF-COMPLIANCE package adds features to measure and validate the RF-signals.At present following hardware is supported:NI USRP-2953NI USRP-2954NI PXIe-5644 (VST)The package is designed for high-load communication, in-depth stressing and debugging the functionality of 802.11p-capable devices in development, validation and research applications.For the API LabVIEW 2014 or higher (development version) is required. The HCM requires LabVIEW 2015 Run-Time Engine as well as suitable device drivers (NI USRP or NI VST), version 15.More Information

Simulate dense traffic/stress 802.11p communication up to the theoretical limit of 802.11p. Catch 802.11p messages for extended monitoring and testing (even invalid frames). Inject erroneous messages overriding MAC control and timing (even with corrupt frame content). Generate precisely timed 802.11p message streams for 802.11p and V2X validation. Get precise timestamps of Rx and Tx activities (coupled to a user-configurable reference clock). Synchronize 802.11p message streams to other signals such as CAN, GNSS simulation, and more. DetailsThe 802.11p Add-On for LabVIEW - MONITORING delivers unique access to the DSRC 802.11p standard in LabVIEW™ for the future V2X (Vehicle-To-Anything) communications based on NI™ hardware platforms NI USRP and NI PXI (VST). It includes (a) a LabVIEW API (functions palette) incl. examples for programming 802.11p-based applications in LabVIEW and (b) the Host Control Manager (HCM) for interaction with the local communication hardware.The MONITORING package enables transmission (send + receive) of regular 802.11p packets (MAC + PHY layer) and offers precise timing of the MPDU-packet output as well as precise time information of the received packets. In addition, the package adds features for failure injection by data and timing manipulation (Packet Replay) as well as monitoring of the data traffic using standardized protocol TZSP.At present following hardware is supported:NI USRP-2953NI USRP-2954 NI PXIe-5644 (VST)The package is designed for high-load communication, in-depth stressing and debugging the functionality of 802.11p-capable devices in development, validation and research applications.For the API LabVIEW 2014 or higher (development version) is required. The HCM requires LabVIEW 2015 Run-Time Engine as well as suitable device drivers (NI USRP or NI VST), version 15.More Information

Simulate dense traffic/stress LTE-V communication up to the theoretical limit of LTE-V. Catch LTE-V messages for extended monitoring and testing (even invalid frames). Inject erroneous messages overriding MAC control and timing (even with corrupt frame content). Generate precisely timed LTE-V message streams for LTE-V and V2X validation. Get precise timestamps of Rx and Tx activities (coupled to a user-configurable reference clock). Synchronize LTE-V message streams to other signals such as CAN, GNSS simulation, and more.DetailsThe LTE-V MONITORING delivers unique access to the 3GPP TS 36.300 (Release 14 / Mode-4 sidelink) standard in LabVIEW™ for the future V2X (Vehicle-To-Anything) communications based on NI™ hardware platform NI USRP. It includes (a) a LabVIEW API (functions palette) incl. examples for programming LTE-V-based applications in LabVIEW and (b) the Host Control Manager (HCM) for interaction with the local communication hardware.The MONITORING package enables transmission (send + receive) of regular LTE-V packets (MAC + PHY layer) and offers precise timing of the MPDU-packet output as well as precise time information of the received packets. In addition the package adds features for failure injection by data and timing manipulation (Packet Replay) as well as monitoring of the data traffic using standardized protocol TZSP.At present following hardware is supported:NI USRP-2953NI USRP-2954The package is designed for high-load communication, in-depth stressing and debugging the functionality of LTE-V-capable devices in development, validation and research applications.For the API LabVIEW 2014 or higher (development version) is required. The HCM requires LabVIEW 2015 Run-Time Engine as well as suitable device drivers (NI USRP or NI VST), version 15.More Information

LTE-V LabVIEW RF-COMPLIANCE for NI VST/USRP and LabVIEW 2015 or higherDetails The LTE-V RF-COMPLIANCE delivers unique access to the 3GPP TS 36.300 standard in LabVIEW™ for the future V2X (Vehicle-To-Anything) communications based on NI™ hardware platform NI USRP. It includes (a) a LabVIEW API (functions palette) incl. examples for programming LTE-V-based applications in LabVIEW and (b) the Host Control Manager (HCM) for interaction with the local communications hardware.The RF-COMPLIANCE package enables transmission (send + receive) of regular LTE-V packets (MAC + PHY layer) and offers precise timing of the MPDU-packet output as well as precise time information of the received packets. In addition to this the RF-COMPLIANCE package adds features to measure and validate the RF-signals.At present following hardware is supported:NI USRP-2953NI USRP-2954NI PXIe-5644 (VST)The package is designed for high-load communication, in-depth stressing and debugging the functionality of LTE-V-capable devices in development, validation and research applications.More Information

RF channel emulation (8-tap) covering V2X standard emulation scenarios. Combinable with V2X communication protocols. Full LabVIEW API for emulation parameter control. Interactive control interface. Applicable to NI software defined radios (USRP or VST Gen. 1). For V2X Add-Ons 802.11p & LTE-V. DetailsThe package is designed to simulate Doppler shift, fading and multipath effects for RF. This software add-on provides the capability to combine all the effects of a signal on 8 different propagation paths (8-tap) in real-time as standalone or in combination with SEA V2X communication add-ons based on NI software defined radios.RF-transmissions are distorted by real world effects altering the wave fronts. These distortions seriously affect the quality and performance of wireless information transmission, especially in traffic oriented RF-applications like V2X. The emulation of these effects is required to test and validate the robustness of receiver setups and chip sets.Typical major physical propagation effects are:attenuationfading by atmospheric effectsDoppler (frequency) shift by relative motion of transmitter and receivermultipath effects resulting from the wavefront being reflected on objects along the propagation pathThe toolkit represents the distorted RF-wavefront of one transmitter (typically vehicle or other traffic object) at the antenna of a receiver. All emulation parameters can be changed actively by a comfortable LabVIEW API.Parameter sets defined by standardization bodies, e.g. ETSI, can be simulated with the CEM toolkit.This toolkit is also available as standalone package or as an integrated component of S.E.A. V2X turnkey test systems for functional testing, RF-behavior measurements and customer specific automated test systems.More Information

Simulate dense traffic/stress 802.11p communication up to the theoretical limit of 802.11p. Catch 802.11p messages for extended monitoring and testing (even invalid frames). Inject erroneous messages overriding MAC control and timing (even with corrupt frame content). Measure RF signals and validate and check for standard compliance all in parallel! Apply typical RF measurement and analysis methods; validate conformity to international standards. For the full feature list, refer to the 802.11p MON and RFC API product pages.DetailsThe 802.11p Add-On for LabVIEW - FULL delivers unique access to the DSRC 802.11p standard in LabVIEW™ for the future V2X (Vehicle-To-Anything) communications based on NI™ hardware platform NI USRP and PXI/VST. It includes (a) a LabVIEW API (functions palette) incl. examples for programming 802.11p-based applications in LabVIEW and (b) the Host Control Manager (HCM) for interaction with the local communications hardware. The FULL package consists of the both, MONITORING and RF-COMPLIANCE packages, that are also available separately.The FULL package enables transmission (send + receive) of regular 802.11p packets (MAC + PHY layer) and offers precise timing of the MPDU-packet output as well as precise time information of the received packets. The MONITORING package adds features for failure injection by data and timing manipulation (Packet Replay) as well as monitoring of the data traffic using standardized protocol TZSP.The RF-COMPLIANCE package adds features to measure and validate the RF-signals.At present following hardware is supported: NI USRP-2953 NI USRP-2954 NI PXIe-5644 (VST) The packages are designed for high-load communication, in-depth stressing and debugging the functionality of 802.11p-capable devices in development, validation and research applications.For the API LabVIEW 2014 or higher (development version) is required. The HCM requires LabVIEW 2015 Run-Time Engine as well as suitable device drivers (NI USRP or NI VST), version 15.More Information

Simulate dense traffic/stress LTE-V communication up to the theoretical limit of LTE-V. Catch LTE-V messages for extended monitoring and testing (even invalid frames). Inject erroneous messages overriding MAC control and timing (even with corrupt frame content). Generate precisely timed LTE-V message streams for LTE-V and V2X validation. Get precise timestamps of Rx and Tx activities (coupled to a user-configurable reference clock). Synchronize LTE-V message streams to other signals such as CAN, GNSS simulation, and more. Contains the Channel Emulation function package. DetailsThe LTE-V MONITORING delivers unique access to the 3GPP TS 36.300 (Release 14 / Mode-4 sidelink) standard in LabVIEW™ for the future V2X (Vehicle-To-Anything) communications based on NI™ hardware platform NI USRP. It includes (a) a LabVIEW API (functions palette) incl. examples for programming LTE-V-based applications in LabVIEW and (b) the Host Control Manager (HCM) for interaction with the local communication hardware. It contains the Channel Emulation function package.The MONITORING package enables transmission (send + receive) of regular LTE-V packets (MAC + PHY layer) and offers precise timing of the MPDU-packet output as well as precise time information of the received packets. In addition the package adds features for failure injection by data and timing manipulation (Packet Replay) as well as monitoring of the data traffic using standardized protocol TZSP.At present following hardware is supported:NI USRP-2953NI USRP-2954The package is designed for high-load communication, in-depth stressing and debugging the functionality of LTE-V-capable devices in development, validation and research applications.For the API LabVIEW 2014 or higher (development version) is required. The HCM requires LabVIEW 2015 Run-Time Engine as well as suitable device drivers (NI USRP or NI VST), version 15.More Information

Contains the Channel Emulation function package. DetailsThe LTE-V RF-COMPLIANCE delivers unique access to the 3GPP TS 36.300 standard in LabVIEW™ for the future V2X (Vehicle-To-Anything) communications based on NI™ hardware platform NI USRP. It includes (a) a LabVIEW API (functions pallete) incl. examples for programming LTE-V-based applications in LabVIEW and (b) the Host Control Manager (HCM) for interaction with the local communications hardware. In addition, it contains the Channel Emulation function package.The RF-COMPLIANCE package enables transmission (send + receive) of regular LTE-V packets (MAC + PHY layer) and offers precise timing of the MPDU-packet output and precise time information of the received packets. In addition to this the RF-COMPLIANCE package adds features to measure and validate the RF-signals.At present following hardware is supported:NI USRP-2953NI USRP-2954NI PXIe-5644 (VST)The package is designed for high-load communication, in-depth stressing and debugging the functionality of LTE-V-capable devices in development, validation and research applications.More Information