Showing results: 196 - 210 of 218 items found.
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780687-01 -
NI
1‑Port, High-Speed, Flexible Data Rate PXI CAN Interface Module—The PXI‑8512 is a high-speed Controller Area Network (CAN) Flexible Data-rate (FD) interface for developing applications with the NI‑XNET driver. The PXI‑8512 excels in applications requiring real-time, high-speed manipulation of hundreds of CAN frames and signals, such as hardware‑in‑the‑loop simulation, rapid control prototyping, bus monitoring, automation control, and more. The NI‑XNET device-driven DMA engine enables the onboard processor to move CAN frames and signals between the interface and the user program without CPU interrupts, minimize message latency and freeing host processor time for processing complex models and applications.
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NI
PXI Vehicle Multiprotocol Interface Modules use hardware-selectable NI-XNET Transceiver Cables (TRC) to communicate High-Speed/Flexible Data‑rate CAN, Low-Speed/Fault Tolerant CAN, and/or LIN. Using the NI-XNET driver, you can create applications that require real-time, high-speed manipulation of hundreds of CAN and/or LIN frames and signals. The NI-XNET device-driven DMA engine enables the onboard processor to move frames and signals between the interface and the user program without CPU interrupts, minimizing message latency and freeing host processor time. PXI Vehicle Multiprotocol Interface Modules work well in applications such as hardware-in-the-loop (HIL) simulation, rapid control prototyping, bus monitoring, and automation control.
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Grid-EYE Evaluation Kit -
Panasonic Automotive & Industrial Systems Europe GmbH
Panasonic Automotive & Industrial Systems has launched this evaluation kit for its Grid-Eye infrared array sensor, which integrates a ”nanopower” Bluetooth Smart module and a microcontroller. The kit is intended for prototyping the Grid-EYE sensor which is a 64 pixel IR camera in a surface mount package measuring 11.6mm x 8mm x 4.3mm, which integrates the MEMS sensor, lens and I2C interface. The integrated Bluetooth module in the evaluation kit, the PAN1740, draws 4.9mA in transmit or receive operating modes, which means it can be powered by coin cell batteries. The IR sensor has 64 thermopile elements in an 8×8 grid format that detect absolute surface temperature without any contact.
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787272-01 -
NI
The Ettus USRP X410 integrates hardware and software to help you prototype high-performance wireless systems and perform over-the-air signal generation and analysis. Additionally, the Ettus USRP X410 features a two-stage superheterodyne architecture with four independent transmitter and receiver channels. It also features a Xilinx Zynq Ultrascale+ RFSoC with programmable FPGA supporting the Open Source UHD tool flow as well as LabVIEW FPGA. With these features, the Ettus USRP X410 has the RF and processing performance for applications such as wireless communications prototyping, spectrum monitoring, and signals intelligence. The Ettus USRP X410 is equipped with a GPS-disciplined 10 MHz oven-controlled crystal oscillator (OCXO) Reference Clock, which improves frequency accuracy and synchronization.
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783150-01 -
NI
50 MHz to 2.2 GHz, GPS-Disciplined OCXO, Reconfigurable USRP Software Defined Radio Device - The USRP-2950 provides an integrated hardware and software solution for rapidly prototyping high-performance wireless communication systems. With the flexible hardware architecture and the LabVIEW unified design flow, researchers can prototype faster and significantly shorten time to results. You can prototype a wide range of advanced research applications that include multiple input, multiple output (MIMO); synchronization of heterogeneous networks; LTE relaying; RF compressive sampling; spectrum sensing; cognitive radio; beamforming; and direction finding. The USRP-2950 is equipped with a GPS-disciplined 10 MHz oven-controlled crystal oscillator (OCXO) reference clock. GPS disciplining delivers improved frequency accuracy and synchronization capabilities.
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783926-01 -
NI
50 MHz to 2.2 GHz, GPS-Disciplined OCXO, Reconfigurable USRP Software Defined Radio Device - The USRP-2950 provides an integrated hardware and software solution for rapidly prototyping high-performance wireless communication systems. With the flexible hardware architecture and the LabVIEW unified design flow, researchers can prototype faster and significantly shorten time to results. You can prototype a wide range of advanced research applications that include multiple input, multiple output (MIMO); synchronization of heterogeneous networks; LTE relaying; RF compressive sampling; spectrum sensing; cognitive radio; beamforming; and direction finding. The USRP-2950 is equipped with a GPS-disciplined 10 MHz oven-controlled crystal oscillator (OCXO) reference clock. GPS disciplining delivers improved frequency accuracy and synchronization capabilities.
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780684-02 -
NI
2-Port, Software‑Selectable/FD CAN Interface Device—The PCI‑8513 is a controller area network (CAN) flexible data-rate (FD) interface for developing applications with the NI‑XNET driver. NI‑XNET software-selectable CAN interfaces offer the best flexibility for CAN development with onboard transceivers for high-speed/FD, low-speed/fault-tolerant, and single-wire CAN as well as any external transceiver. The PCI‑8513 excels in applications requiring real‑time, high‑speed manipulation of hundreds of CAN frames and signals such as hardware‑in‑the‑loop simulation, rapid control prototyping, automation control, and more. The NI‑XNET device‑driven DMA engine enables the onboard processor to move CAN frames and signals between the interface and the user program without CPU interrupts.
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780684-01 -
NI
1‑Port, Software‑Selectable/FD CAN Interface Device—The PCI‑8513 is a controller area network (CAN) flexible data-rate (FD) interface for developing applications with the NI‑XNET driver. NI‑XNET software-selectable CAN interfaces offer the best flexibility for CAN development with onboard transceivers for high-speed/FD, low-speed/fault-tolerant, and single-wire CAN as well as any external transceiver. The PCI‑8513 excels in applications requiring real‑time, high‑speed manipulation of hundreds of CAN frames and signals such as hardware‑in‑the‑loop simulation, rapid control prototyping, automation control, and more. The NI‑XNET device‑driven DMA engine enables the onboard processor to move CAN frames and signals between the interface and the user program without CPU interrupts.
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ARC Technology Solutions
Have time to market pressure and need to get a system or assembly or production line up and running quickly? Need to rapidly build out a solution, but don’t want to spend months on building up an architecture? Allow our rapid prototyping team to assist you – whether it is crafting 3D printed mechanical assemblies or a building up a high speed IO interface, you are in very capable hands with the ARC engineering team. Our DSX product, can help support your IP, implement your process or and be the core processing engine for your design, or if a larger system, DSX could be an integral part of your system. PVS, another tool that can help error-proof your assembly process, is ready to go in a flexible, software-centric solution that you can be reconfigured as needed to meet your changing demands.
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783927-01 -
NI
400 MHz to 4.4 GHz, GPS-Disciplined OCXO, Reconfigurable USRP Software Defined Radio Device - The USRP-2952 provides an integrated hardware and software solution for rapidly prototyping high-performance wireless communication systems. Built on the LabVIEW reconfigurable I/O (RIO) architecture, USRP RIO delivers an integrated hardware and software solution, so researchers can prototype faster and shorten time to results. You can prototype a range of advanced research applications that include multiple input, multiple output (MIMO); synchronization of heterogeneous networks; LTE relaying; RF compressive sampling; spectrum sensing; cognitive radio; beamforming; and direction finding. The USRP-2952 is equipped with a GPS-disciplined 10 MHz oven-controlled crystal oscillator (OCXO) reference clock. GPS disciplining delivers improved frequency accuracy and synchronization capabilities.
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783151-01 -
NI
400 MHz to 4.4 GHz, GPS-Disciplined OCXO, Reconfigurable USRP Software Defined Radio Device - The USRP-2952 provides an integrated hardware and software solution for rapidly prototyping high-performance wireless communication systems. Built on the LabVIEW reconfigurable I/O (RIO) architecture, USRP RIO delivers an integrated hardware and software solution, so researchers can prototype faster and shorten time to results. You can prototype a range of advanced research applications that include multiple input, multiple output (MIMO); synchronization of heterogeneous networks; LTE relaying; RF compressive sampling; spectrum sensing; cognitive radio; beamforming; and direction finding. The USRP-2952 is equipped with a GPS-disciplined 10 MHz oven-controlled crystal oscillator (OCXO) reference clock. GPS disciplining delivers improved frequency accuracy and synchronization capabilities.
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780688-01 -
NI
1‑Port, Software-Selectable PXI CAN Interface Module—The PXI‑8513 is a software-selectable Controller Area Network (CAN) interface for developing applications with the NI‑XNET driver. NI‑XNET Software‑Selectable CAN Interfaces offer the best flexibility for CAN development with onboard transceivers for High-Speed/Flexible Data‑rate, Low-Speed/Fault Tolerant Single Wire CAN as well as any external transceiver. The PXI‑8513 excels in applications requiring real-time, high-speed manipulation of hundreds of CAN frames and signals, such as hardware‑in‑the‑loop simulation, rapid control prototyping, bus monitoring, automation control, and more. The NI‑XNET device-driven DMA engine enables the onboard processor to move CAN frames and signals between the interface and the user program without CPU interrupts.
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780688-02 -
NI
2-Port, Software-Selectable PXI CAN Interface Module—The PXI‑8513 is a software-selectable Controller Area Network (CAN) interface for developing applications with the NI‑XNET driver. NI‑XNET Software‑Selectable CAN Interfaces offer the best flexibility for CAN development with onboard transceivers for High-Speed/Flexible Data‑rate, Low-Speed/Fault Tolerant Single Wire CAN as well as any external transceiver. The PXI‑8513 excels in applications requiring real-time, high-speed manipulation of hundreds of CAN frames and signals, such as hardware‑in‑the‑loop simulation, rapid control prototyping, bus monitoring, automation control, and more. The NI‑XNET device-driven DMA engine enables the onboard processor to move CAN frames and signals between the interface and the user program without CPU interrupts.
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VXI-5524A -
ICS Electronics
*VXI Register Interface mates with user's PCB to form a B or C-size module.* 48 Digital IO Lines - Three 16-bit registers set as latched outputs or gated inputs.* 16 line bi-directional expansion bus for driving external logic.* Digital IO and VXIbus lines are 3.3V logic levels and are 5 V tolerant for compatibility with 3.3V logic and 5V VXIbus signals.* User selectable 3.3 and 5 Vdc puliup voltage on the digital IO lines for sensing switches etc.* The VXI-5524A board is a complete VXI-1 Rev 1.4 and VXI-2 compliant register-based interface.* User configurable model number, manufacturer ID, version and serial numbers.* Two companion component boards available for prototyping IC or RF assemblies.* Companion hardware kits available for building 1, 2 or 3-slot wide modules.
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Ironwood Electronics
For BGA, QFN, or LGA applications, GTP contact technology provides >94 GHz signal speed and can additionally be used in high cycle life applications such as ATE. These sockets support pitches from 0.2 mm to 1.27 mm. Ironwood's GT sockets are ideal for prototyping and testing almost any BGA device application. These IC sockets provide excellent signal integrity yet remain cost effective. Innovative elastomer interconnect technology that delivers low signal loss (1dB at 94GHz) and supports BGA packages with pitches down to 0.2mm was utilized in these sockets. GT BGA sockets are mechanically mounted over a target system's BGA lands using mounting and alignment holes at proper locations (page 2 of the individual socket drawing shows recommended PCB layout information). These low-profile sockets are only 2.5 mm per side larger than actual IC packages (industry's smallest footprint).
