Showing results: 4816 - 4830 of 8184 items found.
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779087-03 -
NI
80 MHz Bandwidth, 16-Bit PXI Waveform Generator - The PXI‑5422 is a 80 MHz arbitrary waveform generator capable of generating user-defined, arbitrary waveforms and standard functions including sine, square, triangle, and ramp. This arbitrary waveform generator can generate signals from -6 V to +6 V and uses direct digital synthesis (DDS) to precisely generate waveforms. The PXI‑5422 also features advanced synchronization and data streaming capabilities.
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779087-04 -
NI
80 MHz Bandwidth, 16-Bit PXI Waveform Generator - The PXI‑5422 is a 80 MHz arbitrary waveform generator capable of generating user-defined, arbitrary waveforms and standard functions including sine, square, triangle, and ramp. This arbitrary waveform generator can generate signals from -6 V to +6 V and uses direct digital synthesis (DDS) to precisely generate waveforms. The PXI‑5422 also features advanced synchronization and data streaming capabilities.
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779087-01 -
NI
80 MHz Bandwidth, 16-Bit PXI Waveform Generator - The PXI‑5422 is a 80 MHz arbitrary waveform generator capable of generating user-defined, arbitrary waveforms and standard functions including sine, square, triangle, and ramp. This arbitrary waveform generator can generate signals from -6 V to +6 V and uses direct digital synthesis (DDS) to precisely generate waveforms. The PXI‑5422 also features advanced synchronization and data streaming capabilities.
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777145-01 -
NI
68-Pin Female VHDCI to 68-Pin Female Screw Terminal, Desktop Mount Terminal Block - The CB-68LP features 68 screw terminals for easy connection of field I/O signals to 68-pin NI data acquisition devices. It includes one 68-pin male SCSI connector for direct connection to 68-pin cables. This connector block features standoff feet for use on a desktop or mounted in a custom panel. The CB-68LP also has a vertical-mounted, 68-pin connector.
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779087-02 -
NI
80 MHz Bandwidth, 16-Bit PXI Waveform Generator - The PXI‑5422 is a 80 MHz arbitrary waveform generator capable of generating user-defined, arbitrary waveforms and standard functions including sine, square, triangle, and ramp. This arbitrary waveform generator can generate signals from -6 V to +6 V and uses direct digital synthesis (DDS) to precisely generate waveforms. The PXI‑5422 also features advanced synchronization and data streaming capabilities.
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QT55 -
Qmax Test Technologies Pvt. Ltd.
Signature Method of Testing is also known as VI Trace Characteristics, is a proven fault diagnostics technique in Power-Off state while testing a board. By applying known wave from signal with desired Voltage, Source impedance and Frequency of the stimulus signals, depending upon the test node and its characteristics, a Voltage (V) vs Current (I) graph is plotted and studied.
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EMC Instruments Corporation
Anechoic chamber, radio isolation room construction, removal, maintenance and repair. System Integration of complete Test System. Development team has the expertise and technical experience and provide a customized service demand, the project includes a full range of EMI / EMS / RF test equipment with neighboring sell and repair reference signal source Noise Generators Signal Generators
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782356-01 -
NI
40 GHz, 50 Ω, Dual 6x1 (SP6T) PXI RF Multiplexer Switch Module—The PXI‑2796 offers a high-density, unterminated multiplexer with dual 6x1 multiplexer banks in the same module. It is ideal for passing high-order harmonics from PXI RF Signal Upconverter modules or routing multiple sources to PXI RF Signal Downconverter modules.
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Teledyne LeCroy
Teledyne Test Tools generate fixed or arbitrarily defined waveforms and signals for use in the development, testing and repair of electronic systems.
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Teledyne LeCroy
Teledyne Test Tools generate fixed or arbitrarily defined waveforms and signals for use in the development, testing and repair of electronic systems.
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ERAVANT
A measurement device that is inserted into the transmission line between an RF source—such as a signal generator, vector network analyzer, or transmitter—and a load.
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MODEL DPM-3 -
Transducer Techniques, Inc
The DPM-3 is a smart Plug & Play TEDS IEEE 1451.4 compliant Digital Panel Mount Load Cell meter. Just plug in a TEDS compatible Load Cell or Torque Sensor and the DPM-3 will automatically self-calibrate. When used with a non-TEDS Load Cell or Torque Sensor, the DPM-3 can be set up by simple front panel push buttons. The DPM-3 can be scaled to a full 5 digit display from 0 to 99,999 counts to read directly in engineering units such as grams, ounces, pounds, etc. The DPM-3 samples 60 readings per second (50 for 50Hz operation) for fast control response and true peak/valley reading capability. The meter has an adaptive digital filter that can automatically select the best time constant for minimum noise, yet respond rapidly to an actual change in signal level. The peak and valley values can be displayed by a push of a button on the front panel. Auto-tare allows the meter to be set to zero for any input signal level. Available options include dual relays, analog output, serial communications, and low voltage power supply.
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ICS Electronics
ICS's Ethernet Parallel Digital Interface boards provide the user with a wide range of IO signals that can be user configured to match virtually any application. These Ethernet boards are available with high power relay driver boards and with optional firmware designed to simplify switching applications. The 80x3 boards have high-power TTL signals that can sink 48 mA and source 24 mA. Pullup resistors make it easy to interface with CMOS logic and to sense contact closures. User configures data byte direction and polarity. The 80x3 boards are VXI-11 compliant for operation with NI or Agilent VISA, LabVIEW and VEE and support raw socket connections. The new 8113 board is a CMOS close of the 8013 board with user set 3.3 or 5 V logic levels. Pinouts and command set is the same as the 8013 board. The 8113 communicates with TCP/IP(Raw Socket) protocoland and also has a RS-232 Serrial Port. All boards are designed for mounting against the rear panel or inside a chassis and use our Ethernet Wiring Kit for easy connection to a Ethernet Connector on the rear panel.
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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.
