Maxim Integrated DS1834AS+T Product Overview

The Maxim Integrated DS1834AS+T is a robust, high-precision microprocessor supervisory circuit designed to monitor power supplies in microprocessor systems. It provides a significant layer of protection by ensuring that the microprocessor always starts up in a known state and by helping to prevent code execution errors during low-voltage conditions.

Key Features

• Power Supply Monitoring: The DS1834AS+T keeps a vigilant watch over the system's power supply, initiating a reset to the microprocessor whenever it detects an out-of-tolerance condition. This ensures reliable operation and stability within the system.
• Adjustable Reset Threshold: Designers can set the reset threshold voltage to match specific system requirements, providing greater control over the conditions that trigger a reset.
• Reset Timeout: The device features a preset timeout that determines the duration of the reset signal, ensuring that the microprocessor has ample time to return to a stable state before resuming operation.
• Low Power Consumption: With its focus on efficiency, the DS1834AS+T is optimized for low power consumption, which is crucial for battery-powered and energy-sensitive applications.
• High Accuracy: The device offers high accuracy in monitoring the power supply, contributing to the overall reliability of the system in which it is deployed.

Applications

The DS1834AS+T is highly versatile and can be used in a variety of applications, including:

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

Package and Availability

The DS1834AS+T comes in a compact surface-mount package, which is suitable for space-constrained applications. Its availability in tape and reel format makes it ideal for automated manufacturing processes, allowing for efficient and streamlined assembly.

With its combination of features, the DS1834AS+T from Maxim Integrated is an excellent choice for designers looking to enhance the reliability and performance of their microprocessor-based systems.