Product Overview: SN74BCT760NSR

The SN74BCT760NSR is a robust integrated circuit designed and manufactured by Texas Instruments, a leader in semiconductor solutions. This device is part of TI's family of octal buffers and line drivers with 3-state outputs, which are designed to drive heavily loaded bus lines or buffer memory address registers. The SN74BCT760NSR is particularly suitable for driving bus lines or buffering memory address registers in systems that require high speed and low power consumption.

Key Features

• Logic Type: Octal Buffer/Line Driver with 3-State Outputs
• Number of Channels: 8
• Output Type: 3-State
• Supply Voltage: 4.5V to 5.5V
• Operating Temperature: -40°C to 85°C
• Package / Case: SOP-20
• Mounting Type: Surface Mount
• Technology: BiCMOS
• Propagation Delay Time: 3.4ns at 5V, 50pF

Applications

The SN74BCT760NSR is versatile and can be used in a variety of applications where high-speed, non-inverting buffer/line drivers are required. It is often found in:

• Memory address driving
• Bus-oriented systems
• Data transmission systems
• Backplane driving

Performance and Quality

Texas Instruments ensures that the SN74BCT760NSR meets stringent quality and performance standards. The device is characterized for operation from -40°C to 85°C, making it reliable in a wide range of environmental conditions. The BiCMOS technology provides the speed of CMOS with the low power consumption and density of bipolar transistors, making it a high-performance solution for modern electronic systems.

Environmental and Regulatory Compliance

The SN74BCT760NSR is RoHS compliant, adhering to environmental standards that restrict the use of hazardous substances in electrical and electronic equipment. This commitment to environmental sustainability makes it an ideal choice for eco-conscious businesses and applications.

With its combination of speed, power efficiency, and robustness, the SN74BCT760NSR from Texas Instruments represents a reliable and versatile solution for a wide range of buffering and driving needs in complex digital systems.