Maxim Integrated MAX6034AEXR30+T Precision Voltage Reference

The MAX6034AEXR30+T is a high-precision voltage reference component from Maxim Integrated, designed to offer a stable and accurate reference voltage for a wide range of applications. This device is part of the MAX6034 series and comes in a compact, surface-mount package, making it suitable for space-constrained applications.

With an output voltage of 3.0V, the MAX6034AEXR30+T is optimized for precision, featuring an initial accuracy of ±0.04% and a low temperature coefficient of 20ppm/°C (max) over the entire operating temperature range of -40°C to +125°C. This ensures that the voltage reference remains highly stable across various environmental conditions, providing a reliable performance for critical applications.

The device operates from a supply voltage range of 2.5V to 5.5V, consuming a low quiescent current of 75µA (typ), which makes it an excellent choice for battery-powered and portable devices where power efficiency is crucial. Additionally, the MAX6034AEXR30+T features a low dropout voltage, allowing it to maintain accurate output even with minimal input-to-output differential, further enhancing its suitability for low-voltage operations.

The MAX6034AEXR30+T comes in a tiny, 5-pin SC70 package, delivering high precision in a small footprint. It is also offered in a tape and reel format, denoted by the "+T" suffix, facilitating easy integration into automated manufacturing processes, which is ideal for mass production.

Applications that benefit from the MAX6034AEXR30+T's performance include high-precision data converters, portable instrumentation, industrial control systems, and precision power supplies. Its stability and accuracy make it an essential component for ensuring the integrity of analog signals and maintaining the overall accuracy of electronic systems.

Maxim Integrated's commitment to quality and performance is evident in the MAX6034AEXR30+T voltage reference, making it a reliable choice for engineers and designers looking to enhance the precision of their electronic designs.