Showing results: 1396 - 1410 of 1542 items found.
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780342-01 -
NI
Virtex-5 LX110 FPGA, 750 kS/s PXI Multifunction Reconfigurable I/O Module—The PXI‑7854 features a user-programmable FPGA for high-performance onboard processing and direct control over I/O signals to ensure complete flexibility of system timing and synchronization. You can customize these devices with the LabVIEW FPGA Module to develop applications requiring precise timing and control such as hardware‑in‑the‑loop testing, custom protocol communication, sensor simulation, and high-speed control. The PXI‑7854 features a dedicated A/D converter (ADC) per channel for independent timing and triggering. This design offers specialized functionality such as multirate sampling and individual channel triggering, which are outside the capabilities of typical data acquisition hardware.
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786455-01 -
NI
PCIe, Kintex-7 160T FPGA, 1 MS/s, Multifunction Reconfigurable I/O Device - The PCIe‑7856 features a user-programmable FPGA for high-performance onboard processing and direct control over I/O signals to ensure complete flexibility of system timing and synchronization. You can customize these devices with the LabVIEW FPGA Module to develop applications requiring precise timing and control such as hardware‑in‑the‑loop testing, custom protocol communication, sensor simulation, and high-speed control. The PCIe‑7856 features a dedicated analog-to-digital converter per channel for independent timing and triggering. This device offers specialized functionality such as multirate sampling and individual channel triggering, which are outside the capabilities of typical data acquisition hardware.
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SEN-30103-J0 -
Playing With Fusion Inc
Analog thermocouple amplifier board based on the AD849x from Analog Devices (successor of the AD597). This quad-channel thermocouple board converts the very low voltage signal from a thermocouple to a highly-linear, 0.005V/C output with either 0V or 1.245V offset (both configurations stocked) while removing unwanted noise from the signal. Many supply and output configurations are available with this board, though the PCB was designed with Arduino in mind. Specifically, the output header will plug directly into a standard Arduino Uno or Mega, with a pin-for-pin match for power supply, ground and analog outputs. With a 5V Arduino, temperatures from 0C to 1,000C are possible with the 0V offset board and -249C to 750C with the 1.245V offset board. If using a 3.3V microcontroller (Due, etc), the board must be supplied with no more than 3.3V to avoid damaging the microcontroller. Temperature measurement range is dependent on the supply voltage. It is possible to supply the board with higher voltages to allow temperature measurement over the entire operating range of the K-Type and J-Type thermocouples, allowing use with more capable data acquisition equipment.
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SEN-30103-J1 -
Playing With Fusion Inc
Analog thermocouple amplifier board based on the AD849x from Analog Devices (successor of the AD597). This quad-channel thermocouple board converts the very low voltage signal from a thermocouple to a highly-linear, 0.005V/C output with either 0V or 1.245V offset (both configurations stocked) while removing unwanted noise from the signal. Many supply and output configurations are available with this board, though the PCB was designed with Arduino in mind. Specifically, the output header will plug directly into a standard Arduino Uno or Mega, with a pin-for-pin match for power supply, ground and analog outputs. With a 5V Arduino, temperatures from 0C to 1,000C are possible with the 0V offset board and -249C to 750C with the 1.245V offset board. If using a 3.3V microcontroller (Due, etc), the board must be supplied with no more than 3.3V to avoid damaging the microcontroller. Temperature measurement range is dependent on the supply voltage. It is possible to supply the board with higher voltages to allow temperature measurement over the entire operating range of the K-Type and J-Type thermocouples, allowing use with more capable data acquisition equipment.
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SEN-30103-K0 -
Playing With Fusion Inc
Analog thermocouple amplifier board based on the AD849x from Analog Devices (successor of the AD597). This quad-channel thermocouple board converts the very low voltage signal from a thermocouple to a highly-linear, 0.005V/C output with either 0V or 1.245V offset (both configurations stocked) while removing unwanted noise from the signal. Many supply and output configurations are available with this board, though the PCB was designed with Arduino in mind. Specifically, the output header will plug directly into a standard Arduino Uno or Mega, with a pin-for-pin match for power supply, ground and analog outputs. With a 5V Arduino, temperatures from 0C to 1,000C are possible with the 0V offset board and -249C to 750C with the 1.245V offset board. If using a 3.3V microcontroller (Due, etc), the board must be supplied with no more than 3.3V to avoid damaging the microcontroller. Temperature measurement range is dependent on the supply voltage. It is possible to supply the board with higher voltages to allow temperature measurement over the entire operating range of the K-Type and J-Type thermocouples, allowing use with more capable data acquisition equipment.
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SEN-30103-K1 -
Playing With Fusion Inc
Analog thermocouple amplifier board based on the AD849x from Analog Devices (successor of the AD597). This quad-channel thermocouple board converts the very low voltage signal from a thermocouple to a highly-linear, 0.005V/C output with either 0V or 1.245V offset (both configurations stocked) while removing unwanted noise from the signal. Many supply and output configurations are available with this board, though the PCB was designed with Arduino in mind. Specifically, the output header will plug directly into a standard Arduino Uno or Mega, with a pin-for-pin match for power supply, ground and analog outputs. With a 5V Arduino, temperatures from 0C to 1,000C are possible with the 0V offset board and -249C to 750C with the 1.245V offset board. If using a 3.3V microcontroller (Due, etc), the board must be supplied with no more than 3.3V to avoid damaging the microcontroller. Temperature measurement range is dependent on the supply voltage. It is possible to supply the board with higher voltages to allow temperature measurement over the entire operating range of the K-Type and J-Type thermocouples, allowing use with more capable data acquisition equipment.
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PX2000-514A (TE1014) -
TEAM SOLUTIONS, INC.
Team Solutions' TE1014 (PX2000-514A) is a 14 slot, 19î rack-mountable chassis, which fully compies with the PXI and Compact PCI standards. All slots have full PXI functionality. Separate forced-air cooling is provided for the power supply and PXI slots. Fan noise is minimized by varying fan speed according to system temperature. Standard features include temperature and PSU monitoring with full software support. The expanded slot capability of the unit provides system integrators with a single-box solution, thus avoiding synchronization, integration and cost issues associated with multi-platform solutions. With a compact case size of 4U / 19î, the TE1014 (PX2000-514A) provides the small footprint required for today's ATE and Data Acquisition applications.
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40-612A-002 -
Pickering Interfaces Ltd.
The 40-612A Very High Density Versatile Multiplexer module features a wide range of software selectable switching configurations. It is especially useful where a number of high density multiplexers are required with the option of easily altering the channel count as a test system evolves. Typical applications include signal routing in ATE and data acquisition systems. The 40-612 module uses high quality electro-mechanical relays, connections are made via a front panel 160 pin DIN41612 connector. The module can be software configured into one of a large number of different multiplexer modes. Relays allow the multiplexer banks to be set in 1 or 2 pole mode and inter-bank switching enables the channel count to be increased up to a maximum of 128
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40-612-002 -
Pickering Interfaces Ltd.
The 40-612 Very High Density Versatile Multiplexer module features a wide range of software selectable switching configurations. It is especially useful where a number of high density multiplexers are required with the option of easily altering the channel count as a test system evolves. Typical applications include signal routing in ATE and data acquisition systems. The 40-612 module uses high quality electro-mechanical relays, connections are made via a front panel 160 pin DIN41612 connector. The module can be software configured into one of a large number of different multiplexer modes. Relays allow the multiplexer banks to be set in 1 or 2 pole mode and inter-bank switching enables the channel count to be increased up to a maximum of 128
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786457-01 -
NI
PCIe, Kintex-7 325T FPGA, 1 MS/s, DRAM Multifunction Reconfigurable I/O Device - The PCIe‑7858 features a user-programmable FPGA for high-performance onboard processing and direct control over I/O signals to ensure complete flexibility of system timing and synchronization. You can customize these devices with the LabVIEW FPGA Module to develop applications requiring precise timing and control such as hardware‑in‑the‑loop testing, custom protocol communication, sensor simulation, and high-speed control. The PCIe‑7858 features a dedicated analog-to-digital converter per channel for independent timing and triggering. This device offers specialized functionality such as multirate sampling and individual channel triggering, which are outside the capabilities of typical data acquisition hardware.
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786458-01 -
NI
PCIe, Kintex-7 160T FPGA, 1 MS/s, DRAM Multifunction Reconfigurable I/O Device - The PCIe‑7857 features a user-programmable FPGA for high-performance onboard processing and direct control over I/O signals to ensure complete flexibility of system timing and synchronization. You can customize these devices with the LabVIEW FPGA Module to develop applications requiring precise timing and control such as hardware‑in‑the‑loop testing, custom protocol communication, sensor simulation, and high-speed control. The PCIe‑7857 features a dedicated analog-to-digital converter per channel for independent timing and triggering. This device offers specialized functionality such as multirate sampling and individual channel triggering, which are outside the capabilities of typical data acquisition hardware.
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787879-01 -
NI
1.33 GHz Dual-Core CPU, 2 GB DRAM, 4 GB Storage, -40 °C to 70 °C, Artix-7 A100T FPGA, Extended Temperature, 4-Slot CompactRIO Controller - The cRIO-9055 is a rugged, deployable controller for data acquisition and control applications. It offers Intel Atom dual-core processing, an Artix-7 FPGA, and four slots for C Series modules. It runs the NI Linux Real-Time operating system with access to the I/O through NI-DAQmx drivers or with the LabVIEW FPGA module. The controller provides precise, synchronized timing and deterministic communications over the network using TSN, ideal for distributed measurements and control. This controller offers two Gigabit Ethernet ports, one USB 3.1 host port, one USB 2.0 device port, a trigger line, and a μSD card slot for storing data locally. 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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787043-01 -
NI
1.33 GHz Dual-Core CPU, 2 GB DRAM, 4 GB Storage, -40 °C to 70 °C, Artix-7 A100T FPGA, Extended Temperature, 4-Slot CompactRIO Controller - The cRIO-9055 is a rugged, deployable controller for data acquisition and control applications. It offers Intel Atom dual-core processing, an Artix-7 FPGA, and four slots for C Series modules. It runs the NI Linux Real-Time operating system with access to the I/O through NI-DAQmx drivers or with the LabVIEW FPGA module. The controller provides precise, synchronized timing and deterministic communications over the network using TSN, ideal for distributed measurements and control. This controller offers two Gigabit Ethernet ports, one USB 3.1 host port, one USB 2.0 device port, a trigger line, and a μSD card slot for storing data locally. 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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Atec, Inc.
Atec has made test equipment throughout all of its 65-year history. Test benches for aerospace and energy uses represent a significant segment of our experience. Atec has produced test benches involving hydraulics, mechanicals, electromechanicals, electronics, pneumatics, motors, and digital automation. Atec test benches have performed for challenging measurements, factory production, problem analysis and component overhaul scenarios. Today, complex test benches have capable data acquisition, control and communication systems integral in their electronics. Atec’s ADAQ™ system, based on COTS components and software, is proven and popular in test bench applications. DCUs, ECUs, FADECs and earlier analog or mechanical control units are easily interfaced.
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Atec, Inc.
Atec’s Data Acquisition and Control System (ADAQ™) is a modern, full-featured, highly integrated hardware and software solution that is applicable for use with most commercial and military turbine engine test cell applications. Built upon National Instruments’ respected LabVIEW platform, ADAQ™ is robust, versatile, user friendly, and specifically designed to handle the demanding requirements of engine testing. It links seamlessly to digital engine modules (FADECs, DEECs, EECs, ECUs) as well as legacy analog and mechanical controls. Users can create, remove, calibrate and display channels, as well as generate custom calculations, screens and reports. Beyond the most impressive manual throttle control and operation available, Atec’s ADAQ™ additionally offers the option of fully automated testing.
