The NXP LD6806CX4/28H is a high-performance, low-dropout voltage regulator designed to deliver a stable and precise output voltage. This compact component is ideal for space-constrained applications requiring efficient power management. With its ability to provide a fixed output voltage of 2.8V, the LD6806CX4/28H is perfect for powering sensitive electronic circuits in a variety of devices, including portable media players, wireless communication modules, and microcontroller-based systems.
Key Features
- Output Voltage: Fixed 2.8V, ensuring consistent performance for connected components.
- Low Dropout: The low dropout feature allows the regulator to continue to provide a stable output voltage even when the input voltage is very close to the output voltage, which is essential for battery-operated devices.
- High Accuracy: The output voltage is maintained with high accuracy, which is crucial for powering sensitive electronic devices that require a stable power supply.
- Current Capability: Capable of supplying up to 150 mA of output current, making it suitable for a range of low-power applications.
- Package: Comes in an ultra-small, leadless 4-pin package (XSON4), which is designed for space-saving PCB designs.
- Temperature Range: Operational over a wide temperature range, ensuring reliability across various operating conditions.
Applications
The LD6806CX4/28H is versatile and can be used in numerous applications where a stable and reliable power supply is necessary. Common applications include, but are not limited to:
- Mobile phones and personal media devices
- Wireless communication systems
- Portable gaming consoles
- GPS receivers
- Healthcare monitoring devices
- Smart sensors and IoT devices
Conclusion
In summary, the NXP LD6806CX4/28H is a reliable and efficient solution for modern electronic devices requiring a fixed 2.8V power supply. Its low dropout, high accuracy, and current capability, combined with a compact package, make it an excellent choice for designers looking to optimize their power management systems in space-constrained applications.