ON Semiconductor MC74VHC374DTR2 Octal D-Type Flip-Flop

The MC74VHC374DTR2 is a high-performance, octal D-type flip-flop integrated circuit from ON Semiconductor, renowned for its advanced silicon technology and precision engineering. This device features eight edge-triggered flip-flops with individual D-type inputs and 3-state outputs, making it an ideal choice for buffering and data storage applications in a wide array of digital systems.

Designed with the modern system designer in mind, the MC74VHC374DTR2 operates with a supply voltage range of 2V to 5.5V, ensuring compatibility with both 3.3V and 5V systems. This flexibility allows the device to be used in various applications ranging from portable electronics to industrial control systems without the need for level shifting. Additionally, the low power consumption and high noise immunity of CMOS technology make this flip-flop a reliable option for battery-operated devices and environments with electrical noise.

The MC74VHC374DTR2 is equipped with eight latches that capture the state of each D input on the rising edge of the clock signal, providing a stable and secure method of data storage. The 3-state outputs allow the device to be directly connected to a bus-structured system, providing both high impedance and active driving states. This feature is particularly useful in bus-oriented systems, where multiple devices need to share common data lines without interference.

ON Semiconductor has packaged the MC74VHC374DTR2 in a TSSOP-20 package, which is not only space-efficient but also offers improved thermal performance and reduced lead inductance. This packaging makes the device suitable for high-density mounting and is an excellent choice for applications where board space is at a premium.

Overall, the MC74VHC374DTR2 from ON Semiconductor is a robust and versatile component that offers reliable performance for a variety of digital applications. Its compatibility with a wide voltage range, low power consumption, and high noise immunity make it an excellent choice for designers looking to create efficient and stable digital systems.