Maxim Integrated MAX6350MJA Voltage Reference
The Maxim Integrated MAX6350MJA is a high-precision, low-noise voltage reference chip designed to provide a stable and accurate reference voltage for analog-to-digital converters (ADCs), digital-to-analog converters (DACs), and other precision circuit applications. This device is a part of Maxim's 6000 series of voltage references, which are renowned for their excellent stability and low noise characteristics.
The MAX6350MJA offers a fixed output voltage of 5V with an impressive initial accuracy of ±0.02%. This level of precision is maintained over the full operating temperature range, thanks to its low temperature coefficient of typically 3ppm/°C, which minimizes the output voltage variation due to temperature changes. The device is capable of sourcing or sinking up to 15mA of output current, providing sufficient drive capability for most applications.
One of the key features of the MAX6350MJA is its low noise output, which is typically 1.5µVp-p for the 0.1Hz to 10Hz bandwidth. This makes it an ideal choice for high-resolution and high-performance systems where noise can significantly impact the overall system accuracy. Additionally, the device includes a trimmed temperature coefficient, which further enhances its performance across various environmental conditions.
The MAX6350MJA comes in a hermetically sealed 8-pin CERDIP package (J-lead), which ensures robustness and reliability, making it suitable for demanding applications in industrial, medical, and high-end instrumentation markets. The package is also designed for through-hole mounting, which simplifies the integration process into existing designs.
For design flexibility, the MAX6350MJA features a no-load stability, ensuring consistent performance even when the output is not actively driving a load. This device also includes short-circuit protection, safeguarding it against potential damage from output overload conditions.
In summary, the Maxim Integrated MAX6350MJA voltage reference combines high precision, low noise, and excellent temperature stability, making it an optimal choice for critical applications where accuracy and reliability are paramount.