The SN74LVTH374DBR is a high-performance, octal-edge-triggered D-type flip-flop designed and manufactured by Texas Instruments. This advanced integrated circuit is part of the LVTH family, which is known for low-voltage, high-speed operation and compatibility with LVTTL and LVCMOS technologies.

Key Features

• Technology: The device is built on BiCMOS technology which offers the advantage of high-speed operation while maintaining the low power dissipation of CMOS circuits.
• Logic Type: It is an octal D-type flip-flop with clear functionality, which means it consists of eight flip-flops with individual D-type inputs and outputs.
• Edge-Triggered: The flip-flops in SN74LVTH374DBR are edge-triggered, capturing data on the rising edge of the clock signal, ensuring precise timing and synchronization in digital circuits.
• 3-State Outputs: This device features 3-state outputs designed to drive heavily loaded outputs with up to 48 mA of continuous current and provide the ability to place the output in a high impedance state, which is essential for bus-oriented applications.
• Wide Operating Voltage Range: The SN74LVTH374DBR operates at a wide range of supply voltages from 2.7V to 3.6V, making it versatile for interfacing with various logic levels in mixed-voltage systems.
• Low Power Consumption: It boasts low power consumption, which is critical for power-sensitive applications.

Applications

The SN74LVTH374DBR is suitable for a broad array of applications. It is commonly used in:

• Memory storage and data management systems
• Communication infrastructure
• Computers and computer peripherals
• Industrial controls
• Data processing equipment

Package and Quality

The device comes in a SSOP (Shrink Small-Outline Package) form factor under the orderable part number SN74LVTH374DBR. This package type is known for its small footprint and suitability for space-constrained applications. Texas Instruments ensures that their products meet rigorous quality standards, and the SN74LVTH374DBR is no exception, offering both reliability and performance for critical digital logic applications.