ON Semiconductor 74AC273MTC Octal D-Type Flip-Flop

The 74AC273MTC from ON Semiconductor is a high-performance, octal D-type flip-flop integrated circuit designed for use in a wide variety of digital applications. This device features eight edge-triggered flip-flops with individual D-type inputs and Q outputs. The common clock (CP) and master reset (MR) inputs allow synchronous reset and control of all flip-flops simultaneously, making this IC ideal for interfacing with bus-structured systems or simple register applications.

Each flip-flop is designed to store a single bit of data and has the ability to transfer data on the positive-going transition of the clock signal. This ensures reliable operation and precise timing for digital circuits. The master reset input is an active-high signal, which when asserted, clears all flip-flops, setting the Q outputs to a low state regardless of the clock input or data inputs.

Constructed with advanced CMOS technology, the 74AC273MTC offers low power dissipation yet high-speed operation. It is capable of operating at a voltage range of 2V to 6V, making it versatile for both low and standard voltage applications. The device also features a high noise immunity characteristic of CMOS technology, ensuring stable performance in electrically noisy environments.

The 74AC273MTC comes in a compact TSSOP-20 package, which is suitable for space-constrained applications. Its surface-mount design allows for efficient assembly in automated manufacturing processes, contributing to reduced production costs and time. The IC is also characterized for operation from -40°C to +85°C, ensuring reliable performance across a broad range of temperature conditions, suitable for industrial and automotive applications.

Whether you are designing a microprocessor system, implementing a high-speed memory buffer, or creating a sequential logic circuit, the ON Semiconductor 74AC273MTC provides a robust and efficient solution for your digital storage needs. Its combination of high speed, low power consumption, and noise immunity makes it a preferred choice for designers looking for reliable and high-performance flip-flop ICs.