Maxim Integrated MAX6306UK31D3-T Voltage Detector

The MAX6306UK31D3-T is a highly precise voltage detector designed by Maxim Integrated, a renowned leader in the development of integrated circuits. This component is engineered to monitor voltages and provide a reliable reset signal to microprocessors (µPs), microcontrollers (MCUs), and other digital systems, ensuring they operate within safe voltage thresholds. With its compact SOT-23 package, the MAX6306UK31D3-T is an ideal solution for space-constrained applications where maintaining power supply integrity is crucial.

Key Features:

• Voltage Threshold: The device features a preset factory voltage threshold of 3.1V, which is suitable for monitoring 3.3V power supplies.
• Reset Timeout: It offers a fixed reset timeout delay of 3 seconds, providing ample time for system stabilization before normal operation resumes.
• Low Power Consumption: The MAX6306UK31D3-T is designed for low power consumption, making it an energy-efficient choice for battery-operated devices.
• High Accuracy: With its precision voltage monitoring, the device ensures that systems are reset under accurate conditions, enhancing overall reliability.
• Operating Temperature Range: It operates over an extended temperature range, from -40°C to +125°C, accommodating various industrial and automotive applications.

Applications:

The MAX6306UK31D3-T is versatile and can be implemented in a wide array of applications, including:

• Computers and Servers
• Embedded Systems
• Portable/Battery-Powered Equipment
• Industrial Controllers
• Automotive Systems

Quality and Reliability:

Maxim Integrated is committed to delivering products that meet the highest standards of quality and reliability. The MAX6306UK31D3-T is no exception, providing dependable performance for critical system monitoring tasks. With its robust design and precise voltage detection capabilities, this voltage detector is a trusted component for safeguarding electronic systems against the potential risks associated with unexpected power fluctuations.