The MAX8517EUB/V+T from Maxim Integrated is a high-precision, low-dropout linear voltage regulator designed to deliver a continuous 150mA of output current. This device is well-suited for portable electronics, where extended battery life is crucial. It offers a low quiescent current and a low dropout voltage, making it an excellent choice for applications requiring efficient power management.
Key Features
- High Accuracy: The MAX8517EUB/V+T provides excellent output voltage accuracy, maintaining stable performance under varying conditions.
- Low Dropout Voltage: This regulator operates with a very low dropout voltage, ensuring efficient use of power and prolonging battery life in portable devices.
- Low Quiescent Current: It has a low quiescent current that minimizes power consumption when in standby mode, which is ideal for battery-powered applications.
- Thermal Overload Protection: The device includes built-in thermal overload protection, which safeguards the regulator and the overall system from excessive temperatures.
- Wide Operating Temperature Range: It is designed to operate over a broad temperature range, making it suitable for various environmental conditions.
Applications
The MAX8517EUB/V+T is versatile and can be used in a wide range of applications, including:
- Battery-Powered Devices
- Portable Media Players
- Handheld Instruments
- Wireless Communication Devices
- Power Supply for DSPs and Microcontrollers
Package and Availability
This voltage regulator is available in a compact, 10-pin μMAX package, which is ideal for space-constrained applications. Its part number indicates it is offered in tape and reel packaging, facilitating efficient assembly for high-volume production. The product is available for purchase through various distributors, ensuring easy integration into your design and supply chain.
Overall, the MAX8517EUB/V+T from Maxim Integrated is a reliable and efficient solution for maintaining stable voltage levels in a multitude of electronic applications, especially where space and power efficiency are critical.