LT1027CCN8-5#PBF - Precision Voltage Reference
The LT1027CCN8-5#PBF is a high-performance, precision voltage reference from Linear Technology. It is designed to provide a stable and accurate reference voltage for high-resolution analog-to-digital converters (ADCs), digital-to-analog converters (DACs), and other precision circuit applications. This voltage reference is characterized by its low noise, high stability, and low temperature coefficient, making it an ideal choice for critical electronic applications where precision is key.
Key Features:
- Output Voltage: The LT1027CCN8-5#PBF provides a fixed 5V output voltage, which is maintained with high accuracy over temperature and time.
- Temperature Coefficient: It has an impressive low temperature coefficient of typically 10ppm/°C, ensuring minimal deviation in output voltage with changes in temperature.
- Low Noise: This device exhibits low noise characteristics, with a typical output noise of 10µVp-p (0.1Hz to 10Hz), providing a clean reference signal for sensitive applications.
- Long-Term Stability: It offers excellent long-term stability, with a typical drift of less than 20ppm per 1000 hours, which is crucial for maintaining precision over the lifespan of the product.
- Supply Voltage Range: The LT1027 operates with a supply voltage range from 7V to 20V, allowing for flexibility in various circuit designs.
- Package: The device comes in an 8-pin PDIP package, which is suitable for through-hole mounting and is easy to integrate into a wide range of electronic systems.
Applications:
The LT1027CCN8-5#PBF is versatile and can be used in numerous applications where a stable reference voltage is critical. Some common applications include:
- Precision data acquisition systems
- High-resolution ADCs and DACs
- Test and measurement equipment
- Medical instruments
- Industrial control systems
With its combination of high precision, stability, and low noise, the LT1027CCN8-5#PBF from Linear Technology is an excellent choice for designers looking to enhance the performance of their electronic systems.