Manufacturer Part Number
AD5331BRUZ
Manufacturer
Analog Devices
Introduction
The AD5331BRUZ is a 10-bit Digital to Analog Converter (DAC) from the Data Acquisition family, designed for precise conversion from digital values to analog voltages.
Product Features and Performance
10-bit resolution with high accuracy
Single DAC output with buffered voltage
Fast settling time of 9µs for responsive performance
External reference for flexible system integration
Parallel data interface for quick data transfer
Operating temperature range from -40°C to 105°C for reliability in extreme conditions
Product Advantages
Precision DAC with tight INL/DNL specifications
Suitable for wide range of supply voltages (2.5V to 5.5V)
Easy to mount with surface-mount 20-TSSOP package
High-temperature tolerance expands usage scenarios
Key Technical Parameters
Number of Bits: 10
Settling Time: 9µs
Voltage Supply, Analog: 2.5V ~ 5.5V
Voltage Supply, Digital: 2.5V ~ 5.5V
INL/DNL (LSB): ±0.5, ±0.05
Operating Temperature Range: -40°C ~ 105°C
Quality and Safety Features
String DAC architecture ensuring consistent performance
Robust package design for improved durability and longevity
Compatibility
Compatible with various microcontrollers and digital systems through parallel interface
Flexible external voltage reference compatibility
Application Areas
Industrial automation and control systems
Data acquisition systems
Digital signal processing
Communication systems
Product Lifecycle
Status: Active
Not reported as nearing discontinuation
Replacements or upgrades should be available but specific details would require additional information
Several Key Reasons to Choose This Product
High-resolution 10-bit DAC for precise applications
Fast settling time suitable for rapid signal processing
Versatile voltage supply range accommodating different power systems
String DAC architecture for reliable and consistent analog output
Extended operating temperature range, ideal for harsh environmental conditions
Manufactured by Analog Devices, a trusted leader in semiconductor technology