The MAX6126AASA25+ is a state-of-the-art, ultra-high-precision, low-noise voltage reference from Maxim Integrated. This component is part of a series of voltage references that feature a high degree of accuracy and stability, making them ideal for critical applications where voltage precision is paramount.
Key Features
- Output Voltage: The device provides a fixed output voltage of 2.5V, suitable for various analog circuits requiring a stable reference voltage.
- High Accuracy: It boasts an impressive initial accuracy of ±0.02%, ensuring minimal deviation in the output voltage.
- Low Temperature Coefficient: The MAX6126AASA25+ has an excellent temperature coefficient, as low as 3ppm/°C, which guarantees consistent performance over a wide temperature range.
- Low Noise: With just 0.6µVp-p of output noise (0.1Hz to 10Hz), it is an excellent choice for sensitive applications such as precision data converters and medical instruments.
- Long-Term Stability: The device offers exceptional long-term stability, minimizing drift over time and ensuring reliability in long-duration applications.
- Supply Voltage Range: It operates with a supply voltage range from 2.7V to 12.6V, providing flexibility in various circuit designs.
- Low Dropout Voltage: The MAX6126AASA25+ features a low dropout voltage, which allows for efficient operation even with minimal difference between the supply and output voltages.
- Package: It comes in an 8-pin SOIC package, making it easy to integrate into a wide range of electronic systems.
Applications
The MAX6126AASA25+ is designed to meet the needs of high-performance applications requiring the utmost precision and stability. It is widely used in:
- Precision data acquisition systems
- High-resolution converters
- Industrial instrumentation
- Medical equipment
- Portable battery-powered devices
- Automotive systems
In summary, the MAX6126AASA25+ from Maxim Integrated is a premium choice for designers seeking an ultra-high-precision voltage reference that combines accuracy, low noise, and high stability in a compact package.