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Analog Devices Inc. AD767JN
- Part Number:
- AD767JN
- Manufacturer:
- Analog Devices Inc.
- Ventron No:
- 3628371-AD767JN
- Description:
- IC DAC 12BIT 24-DIP
- ECAD Model:
-
- Datasheet:
- AD767JN
Analog Devices Inc. AD767JN technical specifications, attributes, parameters and parts with similar specifications to Analog Devices Inc. AD767JN.
- Contact PlatingLead, Tin
- MountThrough Hole
- Mounting TypeThrough Hole
- Package / Case24-DIP (0.300, 7.62mm)
- Number of Pins24
- Operating Temperature0°C~70°C
- PackagingTube
- JESD-609 Codee0
- Pbfree Codeno
- Part StatusObsolete
- Moisture Sensitivity Level (MSL)1 (Unlimited)
- Number of Terminations24
- ECCN CodeEAR99
- Max Power Dissipation600mW
- Terminal PositionDUAL
- Number of Functions1
- Supply Voltage15V
- Terminal Pitch2.53mm
- Base Part NumberAD767
- Pin Count24
- Output TypeVoltage - Buffered
- PolarityBipolar, Unipolar
- Max Supply Voltage16.5V
- Min Supply Voltage11.4V
- Power Dissipation400mW
- Number of Bits12
- Max Output Voltage4V
- Min Input Voltage10.5V
- ArchitectureCurrent Steering
- Max Input Voltage8V
- Converter TypeD/A CONVERTER
- Reference TypeExternal, Internal
- Data InterfaceParallel
- Differential OutputNo
- Resolution1.5 B
- Sampling Rate500 ksps
- Voltage - Supply, Analog±11.4V~16.5V
- Min Output Voltage21V
- Settling Time4μs
- Max Dual Supply Voltage16.5V
- Integral Nonlinearity (INL)1 LSB
- Min Dual Supply Voltage11.4V
- Input Bit CodeBINARY, OFFSET BINARY
- Dual Supply Voltage15V
- Number of Converters1
- Conversion Rate143 ksps
- INL/DNL (LSB)±0.5, ±0.5
- Negative Supply Voltage-Nom-15V
- Height3.3mm
- Length31.75mm
- Width6.35mm
- RoHS StatusNon-RoHS Compliant
- Lead FreeContains Lead
AD767JN Overview
This product features a Through Hole mount and a 24-DIP (0.300, 7.62mm) Package/Case, packaged in a Tube. It has a pin count of 24 and utilizes a Current Steering architecture. The data interface is Parallel and it does not have a Differential Output. The Analog voltage supply range is ±11.4V~16.5V, with a minimum dual supply voltage of 11.4V. It has a fast conversion rate of 143 ksps.
AD767JN Features
24-DIP (0.300, 7.62mm) package
24 pin count
24 pins
Minimal input voltage of 10.5V
AD767JN Applications
There are a lot of Analog Devices Inc. AD767JN Digital to Analog Converters (DAC)?applications.
Servo controls
Low Power Systems
Digitally Controlled Attenuators and Power Supplies
Audio Amplifier
DAT Recorders and Players
Direct Digital Waveform Generation
Instrumentation
Motor Control
Function Generators
Portable Equipment
This product features a Through Hole mount and a 24-DIP (0.300, 7.62mm) Package/Case, packaged in a Tube. It has a pin count of 24 and utilizes a Current Steering architecture. The data interface is Parallel and it does not have a Differential Output. The Analog voltage supply range is ±11.4V~16.5V, with a minimum dual supply voltage of 11.4V. It has a fast conversion rate of 143 ksps.
AD767JN Features
24-DIP (0.300, 7.62mm) package
24 pin count
24 pins
Minimal input voltage of 10.5V
AD767JN Applications
There are a lot of Analog Devices Inc. AD767JN Digital to Analog Converters (DAC)?applications.
Servo controls
Low Power Systems
Digitally Controlled Attenuators and Power Supplies
Audio Amplifier
DAT Recorders and Players
Direct Digital Waveform Generation
Instrumentation
Motor Control
Function Generators
Portable Equipment
AD767JN More Descriptions
DAC 1-CH Current Steering 12-bit 24-Pin PDIP N Tube
24-DIP (0.300 7.62mm) Voltage - Buffered Current Steering R-PDIP-T24 digital to analog converter -15V 4mus 5.33mm 0C~70C
The AD767 is a complete voltage output 12-bit digital-to-analog converter including high stability buried Zener reference and input latch on a single chip. The converter uses 12 precision high-speed biopolar current steering switches and a laser-trimmed thin-film resistor network to provide high accuracy. Microprocessor compatibility is achieved by the on-chip latch. The design of the input latch allows direct interface to 12-bit buses. The latch responds to strobe pulses as short as 40 ns, allowing use with the fastest available microprocessors. The functional completeness and high performance of the AD767 result from a combination of advanced switch design, high-speed biopolar manufacturing process, and the proven laser wafer-trimming (LWT) technology. The subsurface (buried) Zener diode on the chip provides a low-noise voltage reference which has long-term stability and temperature drift characteristics comparable to the best discrete reference diodes. The laser trimming process which provides the excellent linearity is also used to trim the absolute value of the redference as well as its temperature coefficient. The AD767 is thus well suited for wide temperature range performance with ±½ LSB maximum linearity error and guaranteed monotonicity over the full temperature range. Typical full-scale gain is 5 ppm/ºC.
24-DIP (0.300 7.62mm) Voltage - Buffered Current Steering R-PDIP-T24 digital to analog converter -15V 4mus 5.33mm 0C~70C
The AD767 is a complete voltage output 12-bit digital-to-analog converter including high stability buried Zener reference and input latch on a single chip. The converter uses 12 precision high-speed biopolar current steering switches and a laser-trimmed thin-film resistor network to provide high accuracy. Microprocessor compatibility is achieved by the on-chip latch. The design of the input latch allows direct interface to 12-bit buses. The latch responds to strobe pulses as short as 40 ns, allowing use with the fastest available microprocessors. The functional completeness and high performance of the AD767 result from a combination of advanced switch design, high-speed biopolar manufacturing process, and the proven laser wafer-trimming (LWT) technology. The subsurface (buried) Zener diode on the chip provides a low-noise voltage reference which has long-term stability and temperature drift characteristics comparable to the best discrete reference diodes. The laser trimming process which provides the excellent linearity is also used to trim the absolute value of the redference as well as its temperature coefficient. The AD767 is thus well suited for wide temperature range performance with ±½ LSB maximum linearity error and guaranteed monotonicity over the full temperature range. Typical full-scale gain is 5 ppm/ºC.
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