Overview of ADM6315-45D2ARTZ

The ADM6315-45D2ARTZ is a high-performance microprocessor supervisory circuit produced by Analog Devices Inc. This precision device is designed to monitor power supplies in microprocessor and digital systems, providing a significant level of system reliability and accuracy required in critical applications.

Key Features

• Voltage Monitoring Accuracy: The device ensures precise voltage monitoring, with a factory-trimmed reset threshold level of 4.5V, suitable for 5V-powered systems.
• Low Power Consumption: With its low power consumption, the ADM6315-45D2ARTZ is an excellent choice for portable and battery-powered applications.
• Reset Output: It features an active-low, push-pull reset output, which provides a definitive reset signal to the host processor whenever the monitored supply voltage falls below the threshold.
• Reset Timeout: The device offers a minimum reset timeout period of 140ms, ensuring the system has sufficient time to stabilize before normal operation resumes.
• Temperature Range: It operates over a wide temperature range, making it suitable for various environments and applications.
• Small Footprint: The ADM6315-45D2ARTZ comes in a compact SOT-23 package, which is ideal for space-constrained applications.

Applications

This supervisory circuit is versatile and can be used in multiple applications such as:

• Microprocessor systems
• Computers and servers
• Portable/battery-powered equipment
• Industrial controllers
• Embedded systems

Quality and Reliability

Analog Devices Inc. is known for its commitment to quality, and the ADM6315-45D2ARTZ is no exception. It is manufactured to meet high standards, ensuring both performance and durability for the end user. The device's robust design ensures that it can withstand the rigors of daily operation in various industrial and commercial environments.

With its precision voltage monitoring capabilities and low power consumption, the ADM6315-45D2ARTZ is a reliable choice for system designers seeking to enhance the operational stability of their digital systems.