Product Overview: SN64BCT244DW from Texas Instruments

The SN64BCT244DW is a state-of-the-art octal buffer and line driver designed by Texas Instruments to provide high-performance bus interface solutions for a wide range of applications. This integrated circuit is characterized by its exceptional signal integrity and drive capability, making it an ideal choice for situations where buffering and isolation are necessary to maintain data integrity in complex digital systems.

Key Features

• High-Drive Outputs: The SN64BCT244DW can deliver high-current output drive capability of ±64 mA at 5V, which is essential for driving heavy loads or for use in bus-oriented systems.
• Low Power Consumption: This device operates with a low power consumption, ensuring energy efficiency in your designs.
• Bi-Directional Use: It can be used as either an input or output buffer, providing flexibility in application design.
• Wide Operating Temperature Range: The SN64BCT244DW is designed to function over a broad temperature range, from -40°C to +85°C, making it suitable for industrial applications.
• High-Speed Operation: With its fast propagation delay times, this buffer and line driver can support high-speed data transmission, which is essential for modern digital systems.

Product Specifications

• Logic Type: Octal Buffer/Line Driver
• Number of Channels: 8
• Output Type: 3-State
• Supply Voltage: 4.5V to 5.5V
• IC Package Type: SOIC
• Pin Count: 20

Applications

The SN64BCT244DW is versatile and can be integrated into numerous electronic systems. It is commonly used in:

• Data buses
• Memory address drivers
• Control systems
• Buffer memory address registers

With its robust design and reliable performance, the SN64BCT244DW from Texas Instruments is a crucial component for engineers and designers looking to create efficient and high-speed digital interfaces. Whether it's for industrial control systems, data communication equipment, or computer peripherals, this octal buffer and line driver stands out for its ability to maintain signal integrity under demanding conditions.