The SN74LVC821ADWR is a high-performance integrated circuit from Texas Instruments, renowned for its robust design and versatile functionality. This particular device is part of the 74LVC family, which is well-known for its low-voltage operation and compatibility with mixed-voltage systems. It's an ideal choice for designers looking for a reliable and efficient solution for their digital systems.

Key Features

• Logic Type: 10-Bit D-Type Latch with 3-State Outputs
• Supply Voltage Range: 2.7 V to 3.6 V, suitable for low-voltage applications and battery-powered devices.
• Operating Temperature: -40°C to +85°C, ensuring reliability across a wide range of environmental conditions.
• Package: 24-SOIC, providing a compact footprint for space-constrained applications.
• Output Type: 3-State, allowing for bus-oriented applications.

Performance and Applications

The SN74LVC821ADWR is designed for high-speed operation, even at low voltages, making it suitable for interfacing with modern microprocessors and microcontrollers. The 3-state outputs ensure that multiple devices can share a common bus without interference, which is critical in complex digital systems.

This device is commonly used in data storage, retrieval systems, and communication infrastructure where reliable data latching is necessary. Its ability to operate efficiently with a low supply voltage also makes it an excellent choice for portable and power-sensitive applications.

Quality and Reliability

Texas Instruments is a leader in the semiconductor industry, and the SN74LVC821ADWR is built to their stringent quality standards. The device is RoHS compliant, ensuring it meets the latest environmental standards and is free from hazardous substances. Furthermore, its wide operating temperature range guarantees stable performance in diverse operating conditions.

With its combination of performance, efficiency, and reliability, the SN74LVC821ADWR from Texas Instruments is a top-tier choice for designers and engineers looking to incorporate a dependable latching mechanism into their digital logic systems.