Maxim Integrated MAX6018BEUR12+T Voltage Reference

The MAX6018BEUR12+T is a precision, low-dropout, micropower voltage reference from Maxim Integrated. This component is part of a series that is designed to provide a stable and accurate reference voltage for various applications. With its high accuracy and low power consumption, the MAX6018BEUR12+T is ideal for battery-powered devices, portable instrumentation, data converters, and precision power supplies.

This voltage reference features a fixed output voltage of 1.225V, which is maintained over a wide current range of 50µA to 5mA. The device boasts an impressive low dropout voltage of merely 100mV (typical) at a 1mA load, allowing it to function effectively even in low headroom applications. Its low output voltage noise of 15µV RMS (typical) over a 10Hz to 10kHz bandwidth ensures a clean and stable reference for sensitive electronics.

The MAX6018BEUR12+T offers excellent temperature stability, with a temperature coefficient as low as 35ppm/°C (typical), making it reliable across a broad operating temperature range of -40°C to +85°C. This feature ensures that the voltage reference remains precise even under varying environmental conditions.

Designed with a small footprint in mind, the MAX6018BEUR12+T comes in a compact SOT-23 package, making it suitable for space-constrained applications. Its small size, combined with the no external capacitor requirement for stability, allows for a simplified and compact design layout.

With its combination of high accuracy, low power consumption, and small size, the MAX6018BEUR12+T is an excellent choice for designers who need a reliable voltage reference that won't compromise the performance or size of their system. Whether it's for portable medical devices, precision analog-to-digital converters, or any other application requiring a precise reference voltage, the MAX6018BEUR12+T delivers consistent performance in a tiny package.

Overall, the MAX6018BEUR12+T's features make it a versatile and dependable component for ensuring the accuracy and stability of electronic systems.