The MAX8213BESE+T from Maxim Integrated is a high-performance, precision voltage monitor designed to supervise single or multiple system supply voltages. This device is adept at ensuring reliable operation and functionality within electronic systems by monitoring the power supplies and signaling whenever the monitored voltage falls below a preset threshold.

Key Features

• Multiple Voltage Threshold Options: The device is available in a variety of preset voltage threshold levels, making it suitable for a wide range of applications.
• High Accuracy: With precision voltage monitoring, the MAX8213BESE+T ensures tight control over power supply levels, crucial for sensitive electronic circuits.
• Low Power Consumption: Designed to operate with minimal power draw, it is ideal for battery-powered and energy-efficient systems.
• Wide Operating Voltage Range: It supports a broad range of supply voltages, enhancing its versatility across different types of electronic equipment.
• Fast Response Time: The device reacts quickly to under-voltage conditions, providing timely alerts to prevent system failures.

Applications

The MAX8213BESE+T is suitable for a variety of applications where voltage monitoring is critical. These include:

• Computers and Servers
• Portable/Battery-Powered Devices
• Industrial Control Systems
• Telecommunication Equipment
• Medical Devices

Technical Specifications

The device comes in a 16-pin narrow SO package, offering a compact solution for space-constrained applications. It operates over a temperature range of -40°C to +85°C, ensuring reliability across diverse environmental conditions. The MAX8213BESE+T also features an active-low output, which simplifies integration into existing systems by providing a straightforward signaling mechanism when the monitored voltage drops below the acceptable range.

Maxim Integrated's commitment to quality and reliability is evident in the MAX8213BESE+T voltage monitor, making it a top choice for designers and engineers looking to incorporate voltage supervision into their systems.