Maxim Integrated MAX16055BAUB+ Overview

The MAX16055BAUB+ from Maxim Integrated is a highly reliable, compact, and feature-rich supervisory circuit designed to monitor power supplies in digital systems. This device ensures that the system's voltage levels remain within acceptable thresholds, thereby providing a safeguard against power failures, brownouts, and other power-related anomalies. Its small form factor and precision make it an ideal choice for a wide range of applications, including portable devices, computers, embedded systems, and industrial equipment.

Key Features

• Voltage Monitoring: The MAX16055BAUB+ can monitor multiple supply voltages, which is crucial for systems that operate on different power levels. It ensures that each voltage stays within specified limits to prevent damage to sensitive electronic components.
• Adjustable Reset Thresholds: It offers adjustable reset threshold options for greater flexibility in various applications, allowing designers to tailor the supervisory circuit to the specific needs of their system.
• Manual Reset Capability: This device includes a manual reset input, providing a way to initiate a system reset manually. This is useful for system maintenance, troubleshooting, and recovery from fault conditions.
• Low Power Consumption: With its low quiescent current, the MAX16055BAUB+ is energy-efficient, making it suitable for battery-powered applications where power conservation is critical.
• Compact Package: The device comes in a small, 10-pin µMAX package, which is ideal for space-constrained applications. Its tiny footprint allows for integration into compact PCB layouts without sacrificing performance.

Applications

• Portable Electronic Devices
• Networking Equipment
• Computers and Servers
• Embedded Systems
• Industrial Control Systems

The MAX16055BAUB+ supervisory circuit is a testament to Maxim Integrated's commitment to providing advanced circuit protection solutions. Its combination of features ensures that it can deliver reliable performance, safeguarding electronic systems from the risks associated with unpredictable power supply conditions.