The MAX675ESA+ from Maxim Integrated is a precision voltage reference that offers a high degree of accuracy and stability in a variety of applications. This device operates from a single +5V supply and provides a +10V output reference voltage. The MAX675ESA+ is designed in a compact 8-pin NSOIC package, making it suitable for space-constrained applications.
Featuring a low temperature coefficient of only 20ppm/°C (max) over the full operating temperature range, the MAX675ESA+ ensures consistent performance across diverse environmental conditions. This makes it an ideal choice for precision data conversion systems, A/D and D/A converters, and high-resolution measurement equipment.
With a low output noise of 15µVp-p (0.1Hz to 10Hz) and excellent line and load regulation, the MAX675ESA+ delivers a stable and clean reference signal critical for high-performance circuitry. The device also offers a high initial accuracy of ±0.2% (max), which minimizes the need for calibration and simplifies design complexity.
The MAX675ESA+ is equipped with a force-sense connection that corrects for any errors in voltage drop due to the resistance of the PCB traces. This feature ensures that the voltage reference at the load is as accurate as at the device output, providing enhanced precision for critical applications.
Its wide operating temperature range of -40°C to +85°C allows for reliable operation in industrial environments. Additionally, the MAX675ESA+ has a low supply current of 1.4mA (max), which is beneficial for power-sensitive designs. The device also includes a trim terminal for fine-tuning the output voltage, offering designers flexibility in achieving the desired voltage reference accuracy.
Overall, the MAX675ESA+ from Maxim Integrated is a robust and reliable voltage reference that offers exceptional performance characteristics suitable for high-precision electronics. Its combination of accuracy, stability, and low power consumption makes it a versatile choice for engineers and designers looking to enhance the performance of their systems.