Product Overview: MAX6167AESA+ from Maxim Integrated
The MAX6167AESA+ is a precision, low-dropout voltage reference from Maxim Integrated, known for its stability and accuracy in critical applications. This component is designed to provide a fixed voltage output of 2.048V, which is ideal for analog-to-digital conversions, digital-to-analog conversions, and other voltage-sensitive functions. The MAX6167AESA+ comes in a compact 8-pin NSOIC package, making it suitable for space-constrained applications.
With an initial accuracy of ±0.2% and a low temperature coefficient of 20ppm/°C (max), the MAX6167AESA+ ensures consistent performance over a wide temperature range of -40°C to +85°C. This high level of precision is critical for applications requiring a stable reference voltage, such as precision measurement equipment, portable instrumentation, and data acquisition systems.
The device features a low dropout voltage, typically just 200mV at full load, which allows for efficient operation even with a minimal difference between the input and output voltages. This characteristic is particularly beneficial in battery-operated devices, where maximizing the use of available power is crucial.
Additionally, the MAX6167AESA+ boasts an excellent load regulation of 60µV/mA and line regulation of 20µV/V, further contributing to its reliable performance in fluctuating conditions. The device also incorporates a force-sense configuration, which compensates for line drops, enhancing the accuracy of the voltage reference at the point of load.
For designers concerned with power consumption, the MAX6167AESA+ offers a low quiescent current of typically 160µA, making it an energy-efficient choice for portable and battery-powered applications. The product also includes a shutdown feature, allowing the reference to be turned off, thereby reducing the current consumption to under 1µA to conserve energy when not in use.
In summary, the MAX6167AESA+ from Maxim Integrated is a robust, precise voltage reference that delivers consistent performance for a variety of demanding applications. Its combination of accuracy, stability, and power efficiency makes it an excellent choice for designers looking to ensure the integrity of their voltage-sensitive circuits.