Maxim Integrated MAX872ESA+T Precision Voltage Reference

The MAX872ESA+T from Maxim Integrated is a high-precision, low-power voltage reference that offers excellent stability and accuracy for advanced electronic applications. Designed with advanced circuitry, this voltage reference component ensures a stable and precise voltage supply for analog-to-digital converters (ADCs), digital-to-analog converters (DACs), and other sensitive circuitry requiring a stable reference voltage.

Key Features

• Output Voltage: The MAX872ESA+T provides a fixed output voltage of 2.5V, making it suitable for a wide range of applications.
• High Accuracy: It offers an impressive initial accuracy of ±0.15%, ensuring precise performance for critical applications.
• Low Temperature Coefficient: The device has a low temperature coefficient of 10ppm/°C (max), which contributes to its overall stability across varying temperatures.
• Low Supply Current: Operating with a low supply current of 400µA (max), it is ideal for battery-powered and portable devices where power efficiency is crucial.
• Wide Operating Voltage Range: It operates over a wide supply voltage range from 4.5V to 12.6V, providing versatility in different circuit designs.
• Excellent Load Regulation: The MAX872ESA+T features excellent load regulation characteristics, ensuring consistent performance despite changes in the load.

Applications

The MAX872ESA+T is suitable for a variety of applications, including:

• Precision data systems
• High-resolution ADCs and DACs
• Portable instrumentation
• Battery-operated equipment
• Industrial process control systems

Package and Quality

The device is available in a small 8-pin SOIC package, making it easy to integrate into space-constrained designs. Additionally, Maxim Integrated's commitment to quality ensures that each MAX872ESA+T voltage reference meets the highest standards of performance and reliability.

Whether you're designing a sophisticated measurement device or a portable consumer product, the MAX872ESA+T offers the precision and stability needed to achieve accurate and reliable results.