Maxim Integrated MAX6315US26D3 Product Overview

The MAX6315US26D3 is a microprocessor (µP) supervisory circuit designed by Maxim Integrated to monitor power supplies in µP and digital systems. It provides a significant level of system reliability and accuracy required for modern electronic applications. This compact and efficient component is essential for managing system resets and ensuring that the µP operates within safe voltage levels, which is critical for maintaining system stability and data integrity.

Key Features

• Precision Monitoring: The device offers a precise monitoring voltage threshold of 2.63V, suitable for 2.7V to 3.3V power supplies, ensuring that the system operates within its specified voltage range.
• Low Power Consumption: With its low power consumption, the MAX6315US26D3 is ideal for portable and battery-powered applications, helping to extend the operational life of the product.
• Manual Reset Input: The manual reset input allows users to trigger a system reset manually, providing an additional layer of control over the system's operation.
• Reset Timeout: It features a preset timeout delay of 140ms (min), which gives the system enough time to stabilize before it is allowed to resume operation after a reset event.
• Immune to Short VCC Transients: The device is designed to be immune to short-duration transients on the VCC line, ensuring that the system does not experience unnecessary resets due to noise or brief voltage fluctuations.

Applications

• Computers and Controllers
• Embedded Systems
• Portable/Battery-Powered Equipment
• Intelligent Instruments
• Critical µP and µC Power Monitoring

The MAX6315US26D3 is available in a compact SOT-143 package, making it suitable for space-constrained applications. Its robust design and reliable performance make it a preferred choice for designers looking to enhance system safety and performance. With its integrated features, the MAX6315US26D3 from Maxim Integrated is an excellent choice for ensuring that your electronic systems remain operational and secure under various conditions and power supply scenarios.