MAX6162AESA+ Voltage Reference from Maxim Integrated
The MAX6162AESA+ is a precision, low-dropout microprocessor voltage reference from Maxim Integrated, designed to provide a stable and accurate reference voltage for high-performance analog-to-digital converters (ADCs), digital-to-analog converters (DACs), and other high-accuracy analog circuitry. This high-quality voltage reference is a vital component in applications requiring precise voltage calibration, such as medical devices, industrial controls, and precision instrumentation.
The MAX6162AESA+ offers a fixed output voltage of 2.5V with an impressive low temperature coefficient of only 3ppm/°C, ensuring minimal deviation over the entire operating temperature range. This level of precision is critical in maintaining the performance of sensitive electronic systems across various environmental conditions. The device also boasts a low dropout voltage, which enables it to maintain a stable output even when the supply voltage is close to the output voltage, making it highly efficient for battery-powered applications.
With a maximum supply current of only 85µA, the MAX6162AESA+ is optimized for low-power operations, which is essential for extending battery life in portable devices. The low supply current, combined with a wide supply voltage range from +2.7V to +12.6V, provides design flexibility and compatibility with a variety of power sources and system architectures.
The MAX6162AESA+ comes in a compact 8-pin SOIC package, which is ideal for space-constrained applications. It also features a force-sense configuration that allows for remote voltage sensing, compensating for voltage drops due to PCB trace resistances, thereby preserving the accuracy of the voltage reference at the point of load. Furthermore, the device includes a thermal shutdown feature that protects it from overheating, thereby enhancing the reliability and longevity of the product.
Overall, the MAX6162AESA+ from Maxim Integrated is a reliable and precise voltage reference that offers excellent temperature stability, low power consumption, and a small footprint, making it an ideal choice for a wide range of high-accuracy applications.