The ASM810SEURF-T from ON Semiconductor is a highly reliable, precision microprocessor voltage supervisor designed to maintain system integrity during power failures or unexpected power-down events. This component is an essential device for a wide range of applications that require a stable and secure operation, including consumer electronics, automotive systems, and industrial controls.

Key Features:

• Precision Monitoring: The voltage supervisor accurately monitors the system voltage, ensuring that the microprocessor and other critical components receive a stable supply, which is crucial for maintaining system performance and preventing data loss.
• Low Power Consumption: With its low power consumption, the ASM810SEURF-T is an excellent choice for battery-powered devices, contributing to longer battery life and reduced energy costs.
• Reset Output: The device provides an active-low reset output, which is asserted when the monitored voltage falls below the factory-programmed threshold, ensuring that the system resets reliably and returns to a known state.
• Manual Reset Input: A manual reset input allows for an external trigger to initiate a system reset, offering additional control to the user or system designer.
• High Accuracy: The voltage threshold accuracy is maintained over the full temperature range, which is critical for applications operating under varying environmental conditions.

Product Specifications:

• Package: The ASM810SEURF-T comes in a compact SOT-23 package, making it suitable for space-constrained applications.
• Operating Temperature: It is designed to operate over a wide temperature range, ensuring reliability in diverse operating conditions.
• Threshold Voltage: The device features a precise factory-programmed threshold voltage for accurate monitoring.

The ON Semiconductor ASM810SEURF-T voltage supervisor is a crucial component for systems that cannot afford to compromise on reliability and accuracy. Its robust design and comprehensive features make it a versatile solution for maintaining system stability across various applications.