Showing results: 121 - 135 of 1986 items found.
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NI
The C Series Current Input Module features programmable input ranges, variable connectivity options, and built-in noise rejection. You can also choose from options with built-in anti-aliasing filters or high-channel density to reduce the number of modules needed. The C Series Current Input Module supports safety features, certifications, input ranges, overvoltage ranges, and connectivity for applications such as power quality monitoring and metering, utility pole-mounted smart switches, utility pole-mounted smart grid reclosers, substation merging units, industrial machine measurements, health monitoring, predictive maintenance and prognostics, and phasor measurement units (PMUs). The C Series Current Input Module includes the NI-DAQmx driver and configuration utility that simplify configuration and measurements. NI-DAQmx supports NI programming environments as well as Python, ANSI C, C#.NET, and MathWorks MATLAB® software.
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NI
The PXI Vector Signal Transceiver (VST) combines the flexibility of a software defined radio architecture and RF instrument class performance. You can use the VST to test a variety of cellular and wireless standards, and you can easily expand the VST's three-slot, 3U PXI Express form factor to support multiple input, multiple output (MIMO) configurations. The VST software is built on LabVIEW FPGA, and features several starting points for your application including application IP, reference designs, examples, and LabVIEW sample projects.
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NI
PXI Programmable Power Supply modules feature multiplechannels that you can combine for higher voltage or current capabilities. Some modules include isolatedchannels and an output disconnect functionality that allows isolation from the device under test(DUT) when not in use and remote sense to correct for losses in system wiring. You can use these models to simplify the task of designing automated test systems for a wide range of applicationsfrom aerospace and defense to automotive and component testby eliminating the need to mix multiple instrumentation form factors in a given test system.
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NI
PXI RF Analog Signal Generators deliver the functionality of RF signal generators to the modular, compact PXI form factor. These modules support frequency ranges from 250 kHz to 20 GHz. You can combine PXI RF Analog Signal Generators with other PXI modular instrumentation to design automated test systems for radar, RF integrated circuits (RFICs), and automotive test applications.
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NI
PXI Vector Signal Analyzers feature a wide frequency range, real-time signal analysis, and advanced signal processing. PXI Vector Signal Analyzers can perform measurements for a broad range of wireless technologies such as GSM, EDGE, WCDMA, LTE-Advance Pro, 5G, Wireless LAN, and Bluetooth. Select models also feature a LabVIEW-programmable FPGA that you can customize for advanced measurement applications. PXI Vector Signal Analyzers are ideal for microwave test, wireless test, RADAR test, spectral monitoring, software-defined radio (SDR), radio monitoring, interference detection, signal intelligence, and other applications.
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NI
PXI RF Matrix Switch Modules are organized into rows and columns and provide maximum flexibility for switching systems by allowing you to connect any channel to any other channel. PXI RF Matrix Switch Modules use a variety of relay types, including electromechanical armature relays, reed relays, field-effect transistor (FET) relays, and solid-state relays, each with their own benefits, allowing you to choose a matrix that fits your requirements. To program the switches, you can use the IVI-compliant NI-SWITCH driver software, complete with help documentation, example programs, and a soft front panel application for interactive control of switches. For intelligent management of complex switch systems, NI Switch Executive provides additional software tools to help you design, build, and deploy your switching system.
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NI
The Digital Reconfigurable I/O (RIO) Device features user-programmable FPGA for onboard processing and flexible I/O operation. You have complete control over the synchronization and timing of all signals and operations along with custom onboard decision-making that executes with hardware-timed speed and reliability. You can configure user-defined hardware for a wide variety of applications, such as custom digital DAQ, high-speed waveform generation, sensor simulation, hardware-in-the-loop (HIL) test, custom digital communications protocols, bit error rate testing, and other applications that require precise timing and control.
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NI
The USRP Software Defined Radio Reconfigurable Device is built on the LabVIEW reconfigurable I/O (RIO) and universal software radio peripheral (USRP) architectures. It includes a powerful FPGA for advanced DSP that you can program with the LabVIEW FPGA Module. The device includes 2x2 MIMO transceivers or four-channel superheterodyne receivers, supporting center frequencies from 10 MHz to 6 GHz, with up to 160 MHz of instantaneous bandwidth. The USRP Software Defined Radio Reconfigurable Device also optionally includes a GPS‐disciplined oven-controlled crystal oscillator (GPSDO), which provides greater frequency accuracy than temperature- compensated crystal oscillators. Prototyping applications include LTE and 802.11 prototyping, spectrum monitoring, signals intelligence, military communications, radar, direction finding, and wireless research.
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NI
PXI Frame Grabber Modules work with any base-, medium, and full-configuration Camera Link cameras, and are ideal for many industrial, life science, and biomedical imaging applications. PXI Frame Grabber Modules support Power over Camera Link(PoCL) and can power cameras through PoCL-enabled cables. You can program the PXI Frame Grabber Module using the NIVision Development Module, or you can configure it using NIVision Builder for Automated Inspection(AI) software for faster development and simplified maintenance.
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NI
Transceiver Cables are designed to provide flexibility in connecting a bus to various devices on the PXI, CompactRIO, and CompactDAQ platforms. Each isolated cable includes the necessary transceiver for the bus type. The cables also feature termination resistors that you can enable or disable in software. You can use the NI-XNET driver to program and configure the Transceiver Cables.
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NI
PXI GPIB Instrument Control Modules feature IEEE 488 controllers for PXI systems. You can choose an option that supports Gigabit Ethernet transfer speeds. PXI GPIB Instrument Control Modules include a license for the industry standard NI-488.2 driver software enabling reliable connections to third-party instruments with GPIB.
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NI
PXI Digital Reconfigurable I/O Modules feature a user-programmable FPGA for onboard processing and flexible I/O operation. You can completely control the synchronization and timing of all signals and operations along with custom onboard decision making. The PXI Digital Reconfigurable I/O Module is suited for a wide variety of applications, such as high-speed waveform generation, sensor simulation, hardware-in-the-loop (HIL) test, custom communications protocols, bit error rate testing, and other applications requiring precise timing and control.
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NI
PXI SMUs are shipped with an interactive soft front panel for ready-to-run measurements. It includes two modes: one for constantly outputting a DC current or voltage and another for multichannel sweeps. You can monitor and debug the instrument during automated measurement by enabling a debug session.
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NI
The USRP Software Defined Radio Stand-Alone Device consists of an onboard processor, FPGA, and RF front end. You can program this device using either LabVIEW Communications System Design Suite or an open-source software workflow, depending on the operating system you choose. You can provision the device with NI Linux Real-Time, Linux Fedora, or Linux Ubuntu real-time operating systems. The USRP Software Defined Radio Stand-Alone Device enables you to prototype a range of advanced research applications such as stand-alone LTE or 802.11 device emulation; Medium Access Control (MAC) algorithm development; multiple input, multiple output (MIMO); heterogeneous networks; LTE relaying; RF compressive sampling; spectrum sensing; cognitive radio; beamforming; and direction finding.The registered trademark Linux® is used pursuant to a sublicense from LMI, the exclusive licensee of Linus Torvalds, owner of the mark on a worldwide basis.
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NI
The USRP Software Defined Radio Device is a reconfigurable RF device that includes a combination of host-based processors, FPGAs, and RF front ends. The USRP Software Defined Radio Device include options that range from lower cost options with fixed FPGA personalities to high-end radios with a large, open FPGAs and wide instantaneous bandwidth. These devices can be used for applications such as multiple input, multiple output (MIMO) and LTE/WiFi testbeds, SIGINT, and radar systems.
