Product Overview: MAX6307UK4403-T from Maxim Integrated

The MAX6307UK4403-T is a robust, precision microprocessor (µP) supervisory circuit designed by Maxim Integrated to monitor power supplies in digital systems. It provides excellent circuit reliability and low cost by eliminating external components and adjustments when used in systems with a 4.4V power supply voltage.

Key Features

• Voltage Monitoring: This device keeps a watchful eye on the system's power supply, ensuring that the microprocessor and other critical components operate within the specified voltage range for optimal performance.
• Reset Output: In the event of a power supply dip below the preset threshold, the MAX6307UK4403-T asserts a reset signal to prevent system errors. The reset output remains active until the supply voltage recovers and stabilizes, ensuring a proper system restart.
• Manual Reset: An additional manual reset input allows for an external trigger to initiate a system reset, providing an extra layer of control for system management and debugging.
• Low Power Consumption: Designed for energy-efficient applications, this supervisory circuit minimizes the power draw from the system, contributing to overall power conservation.
• Compact SOT23 Package: The device comes in a small, surface-mount SOT23 package, making it suitable for space-constrained applications without compromising functionality.

Applications

The MAX6307UK4403-T is versatile and can be used in a variety of applications where reliable system monitoring is crucial. Common applications include:

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

Quality and Reliability

Maxim Integrated is known for their commitment to quality, and the MAX6307UK4403-T is no exception. It is built to meet high standards, ensuring stable and reliable performance in a broad range of operating conditions. This supervisory circuit is a testament to Maxim Integrated's dedication to providing components that system designers can trust to maintain the integrity of their digital systems.