Maxim Integrated MAX1976AEZT110+T Voltage Regulator
The MAX1976AEZT110+T is a high-performance, low-dropout linear regulator designed by Maxim Integrated, aimed at delivering a precise voltage supply for a wide range of applications. This component is well-suited for systems that require a stable and efficient power source, and it is particularly useful in scenarios where minimal power dissipation and low voltage operation are critical.
Key Features
- Output Voltage: The device provides a fixed output voltage of 1.1V, which is ideal for low-voltage operations in modern electronic circuits.
- High Accuracy: It boasts an impressive output voltage accuracy of ±1%, ensuring reliable performance and consistent power delivery to sensitive components.
- Low Dropout: With a low dropout voltage, the MAX1976AEZT110+T maintains regulation even when the input-to-output differential is minimal, making it highly efficient in battery-powered devices.
- Thermal Protection: The regulator includes an over-temperature protection feature, safeguarding the device against excessive heat and ensuring long-term reliability.
- Package: Encased in a compact, 6-pin SOT-23 package, the MAX1976AEZT110+T is designed for space-constrained applications.
- Operating Temperature Range: It can operate over a wide temperature range from -40°C to +85°C, accommodating various environmental conditions.
Applications
The MAX1976AEZT110+T is versatile and can be used in various electronic devices, including:
- Portable and battery-powered devices
- Notebook computers
- Cellular phones
- Handheld instruments
- Wireless LAN devices
Conclusion
Maxim Integrated's MAX1976AEZT110+T is a robust and efficient solution for systems that demand a stable low-voltage power supply. Its low dropout voltage, high accuracy, and thermal protection make it an excellent choice for designers looking to enhance the performance and reliability of their electronic products. The compact form factor of the SOT-23 package further ensures that this voltage regulator can be integrated into space-sensitive applications without sacrificing functionality or performance.