Showing results: 1846 - 1860 of 2536 items found.
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780178-01 -
NI
2-Port, High-Speed C Series CAN Interface Module—The NI‑9853 is a high-speed Controller Area Network (CAN) interface for developing FPGA-based applications with the NI‑RIO driver on CompactRIO. The NI‑9853 is ideal for low-level FPGA‑based control and triggering applications that are programmed using the LabVIEW FPGA Module. The NI‑9853 is ideal for byte-level manipulation of CAN frames using the LabVIEW FPGA Module. The NI‑9853 is only compatible with CompactRIO systems.
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779429-01 -
NI
2-Port, High-Speed C Series CAN Interface Module—The NI‑9853 is a high-speed Controller Area Network (CAN) interface for developing FPGA-based applications with the NI‑RIO driver on CompactRIO. The NI‑9853 is ideal for low-level FPGA‑based control and triggering applications that are programmed using the LabVIEW FPGA Module. The NI‑9853 is ideal for byte-level manipulation of CAN frames using the LabVIEW FPGA Module. The NI‑9853 is only compatible with CompactRIO systems.
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N1500A -
Keysight Technologies
With Keysight N1500A materials measurement software suite, you can determine the intrinsic electromagnetic properties of many dielectric and magnetic materials. The complete system is based on a versatile Keysight network analyzer which measures the material’s response to RF or microwave energy. The N1500A software controls the network analyzer and calculates results. Depending on the Keysight network analyzer and sample holder or fixture used, frequencies can extend from a few hundred MHz into the low THz.
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F1V04 -
Beijing SANKI Petroleum Technology Co., Ltd.
The main board issues a start signal and a low voltage signal (12v) for opening the electromagnetic valve, which are converted into strong voltage signals (220 VAC) to drive the electromagnetic valve (380 VAC) and the motor in our fuel dispensers system, thus completing the function of conversion from weak voltage power to strong voltage power. The control board circuit isolates high voltage interference signals via photoelectrical isolating components.
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SIU32-FCCVARM-01 -
North Atlantic Industries
SIU32-FCCVARM-01 is a Modular Open Systems Approach (MOSA) DO-178C & DO-254 Certifiable Flight Control Computer (FCC) with low power high performance OpenVPX Xilinx UltraScale+ SBC with Quad Core ARM Cortex -A53, 8 GB DDR4 SDRAM, 32 GB SATA Flash, 2 x 10/100/1000Base-T Ethernet, USB 3.0, FIPS-140-3 Level 3 Cyber Security, and Single Event Upset support.
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PCIe-PXIe-8638 -
ADLINK Technology Inc.
The PCIe-PXIe-8638 PCI Express-to-PXI Express expansion kit provides control of PXI Express modules installed in a PXI Express chassis using high bandwidth PCI Express technology. The extension kit can provide up to 4GB/s using PCIe Gen 2 x8 signaling. With comprehensive hardware and software transparency, the expansion kit enables fast and convenient detection of any PXI cards installed in the system, requiring no additional drivers or software.
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NI
The Analog Output Module for Remote I/O features a 2-wire spring terminal connection, selectable output ranges (0 V to 10 V, ±10 V, 0 V to 5 V, ±5 V, 0 mA to 20 mA, 4 mA to 20 mA, and ±20 mA) output ranges, and short circuit proof outputs. A remote I/O system consists of an EtherCAT bus coupler and individual modules mounted on a DIN rail. You control the Analog Output Module for Remote I/O from a real‐time controller, such as a CompactRIO Controller or an Industrial Controller. You can use remote I/O hardware to add low‐cost I/O for simple tasks while your controller handles advanced tasks such as image processing, motion control, and high‐speed or specialty measurements.
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SparkFun Electronics
Using our muscles to control things is the way that most of us are accustomed to doing it. We push buttons, pull levers, move joysticks... but what if we could take the buttons, levers and joysticks out of the equation and control it with our muscles? The MyoWare® 2.0 Muscle Sensor is an Arduino-compatible, all-in-one electromyography (EMG) sensor from Advancer Technologies that allows you to do just that! The MyoWare 2.0 Muscle Sensor has been redesigned from the ground up with a new easy-to-use, compact design and upgraded with the latest and greatest chipset improving sensor performance and reliability. The innovative snap connector system eliminates the need to solder connections for the MyoWare 2.0 ecosystem. It's that easy: stick on a few electrodes (not included), read the output voltage and flex some muscles!
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M4K1553Px(S)-1760 -
Excalibur Systems, Inc.
The M4K1553Px(S)-1760 interface module for the multimode, multiprotocol, Excalibur 4000 family of carrier boards provide a complete solution for developing and testing MIL-STD-1760 interfaces and performing system simulation of the MIL-STD-1760 bus. The module handles all standard variations of the MIL-STD-1760 protocol.Each M4K1553Px-1760 multi function module contains 64K bytes of dual-port RAM for Data blocks, Control registers, and Look-up Tables. All Data blocks and Control registers are memory mapped, and may be accessed in real time. Each of the independent dual redundant M4K1553Px-1760 modules may be programmed to operate in one of three modes of operation: Remote Terminal, Bus Controller/Concurrent-RT, and Bus Monitor. In addition, modules 1 and 3 can be programmed to operate as Concurrent monitors, to modules 0 and 2 respectively.
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787455-01 -
NI
The PXIe-1486 combines the Texas Instruments Flat Panel Display Link™ (FPD-Link™) interface with the Xilinx FPGA for high-throughput vision and imaging applications. This module provides a high-speed digital interface for using and testing modern advanced driver assistance systems (ADAS) and autonomous drive (AD) camera sensors and electronic control units (ECUs). Additionally, the PXIe-1486 makes use of a combination of FPD-Link™ serializers and deserializers with a Xilinx FPGA to provide a high-throughput and customizable FPD-Link™ interface on PXI. The included FlexRIO driver, with LabVIEW FPGA examples, provides access and control for power-over-coax, I²C back-channel communication, and general-purpose input/output (GPIO) communication on the FPD-Link™ channels. The PXIe-1486 is ideal for applications such as in-vehicle data logging, lab-based playback, or hardware-in-the-loop (HIL). FPD-Link is a trademark of Texas Instruments.
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787454-01 -
NI
The PXIe-1486 combines the Texas Instruments Flat Panel Display Link™ (FPD-Link™) interface with the Xilinx FPGA for high-throughput vision and imaging applications. This module provides a high-speed digital interface for using and testing modern advanced driver assistance systems (ADAS) and autonomous drive (AD) camera sensors and electronic control units (ECUs). Additionally, the PXIe-1486 makes use of a combination of FPD-Link™ serializers and deserializers with a Xilinx FPGA to provide a high-throughput and customizable FPD-Link™ interface on PXI. The included FlexRIO driver, with LabVIEW FPGA examples, provides access and control for power-over-coax, I²C back-channel communication, and general-purpose input/output (GPIO) communication on the FPD-Link™ channels. The PXIe-1486 is ideal for applications such as in-vehicle data logging, lab-based playback, or hardware-in-the-loop (HIL). FPD-Link is a trademark of Texas Instruments.
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787453-01 -
NI
The PXIe-1486 combines the Texas Instruments Flat Panel Display Link™ (FPD-Link™) interface with the Xilinx FPGA for high-throughput vision and imaging applications. This module provides a … high-speed digital interface for using and testing modern advanced driver assistance systems (ADAS) and autonomous drive (AD) camera sensors and electronic control units (ECUs). Additionally, the PXIe-1486 makes use of a combination of FPD-Link™ serializers and deserializers with a Xilinx FPGA to provide a high-throughput and customizable FPD-Link™ interface on PXI. The included FlexRIO driver, with LabVIEW FPGA examples, provides access and control for power-over-coax, I²C back-channel communication, and general-purpose input/output (GPIO) communication on the FPD-Link™ channels. The PXIe-1486 is ideal for applications such as in-vehicle data logging, lab-based playback, or hardware-in-the-loop (HIL). FPD-Link is a trademark of Texas Instruments.
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ADIS16490 iSensor -
Analog Devices Inc.
The ADIS16490 iSensor® device is a complete inertial system that includes a triaxial gyroscope and a triaxial accelerometer. Each inertial sensor in the ADIS16490 combines industry-leading iMEMS® technology with signal conditioning that optimizes dynamic performance. The factory calibration characterizes each sensor for sensitivity, bias, alignment, and linear acceleration (gyroscope bias). As a result, each sensor has its own dynamic compensation formulas that provide accurate sensor measurements. The ADIS16490 provides a simple, cost-effective method for integrating accurate, multiaxis inertial sensing into industrial systems, especially when compared with the complexity and investment associated with discrete designs. All necessary motion testing and calibration are part of the production process at the factory, greatly reducing system integration time. Tight orthogonal alignment simplifies inertial frame alignment in navigation systems. The SPI and register structure provide a simple interface for data collection and configuration control.
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TLP-12010C -
High Power Pulse Instruments GmbH
- High pulse output current up to 120 A (short circuit)- Ultra-fast 50 Ω high voltage pulse output with typical rise time 100 ps (0 A to 40 A) and 300 ps in high-current mode (0 A to 120 A)- Wafer, package and system level TLP, VF-TLP and HMM testing- Up to 180 kW peak output power into 50 Ω load- Built-in HMM pulse up to ±32 kV in 50 Ω-configuration- High speed 50 Ω trigger output for oscilloscopes (synchronous to high voltage pulse output)- 6 USB programmable pulse rise times: 100 ps to 50 ns (custom selectable)- 8 (optional 9) programmable pulse widths: 0.5 ns (optional), 1 ns to 100 ns (0 A to 40 A), 1 built-in pulse width: 100 ns (>40 A)- The optional pulse width extender TLP-3011C enables pulse width up to 1.6 µs in 68 GPIB programmable steps (0 A to 40 A)- Optional external pulse width extensions from 5 ns to 500 ns (>40 A to 120 A)using the external pulse width extender TLP-12012A6- Built-in pulse reflection suppression- Fast measurement time, typically less than 0.2 s per pulse including one-point DC measurement between pulses- Efficient sofware for system control and waveform data management- The sofware can control automatic probers for fast measurements of complete wafers- Combines TLP-12010A and TLP-4010C into one system- Can be operated together with TLP-12012A6 and TLP-3011C pulse width extenders- Integrated interlock safety shut-down- Industrial isolated and EMI/ESD protected USB control interface
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PEMS -
ABB Ltd.
Predictive Emission Monitoring Systems are software-based solutions able to deliver reliable real-time emission estimations exploiting advanced mathematical or statistical models. PEMS provide accurate emission monitoring, drastically reducing the capital investment and ongoing operating costs due to maintenance activities and spare parts, minimizing the interferences with plant operations. PEMS allows plant owners and operators a better control on costs, neglecting unexpected costs due to unpredicted issues in the conventional hardware analyzers.
