The SN74AC533DWR is a high-performance, integrated circuit product designed and manufactured by Texas Instruments (TI), a leader in semiconductor solutions. This device is part of TI's SN74AC series, known for its robustness and reliability in a wide range of digital applications.

Key Features

• Type: Octal D-Type Flip-Flop with Clear
• Logic Family: AC
• Output Type: 3-State
• Operating Temperature Range: -40°C to +85°C
• Package / Case: SOIC-20
• Mounting Type: Surface Mount
• Supply Voltage: 2V to 6V
• Propagation Delay Time: 8ns at 5V, 50pF
• IC Interface Type: CMOS

Product Description

The SN74AC533DWR is specifically engineered to address the needs of high-speed data storage and transfer in digital systems. This octal D-type flip-flop features eight edge-triggered D-type flip-flops with individual D inputs and Q outputs. The clear (CLR) input has a direct effect on the flip-flops, ensuring that the Q outputs are in a low state when the CLR input is held high.

One of the standout features of the SN74AC533DWR is its 3-state outputs, which are designed to drive bus lines or buffer memory address registers. This ability to place the output in a high-impedance state is crucial when multiple devices are connected to a common bus, as it prevents bus contention.

The device operates over a broad voltage range from 2V to 6V and is characterized for operation from -40°C to +85°C, making it suitable for a variety of demanding environments. Its propagation delay time is remarkably fast, which is essential for high-speed operations in modern digital systems.

Housed in a slim SOIC-20 package, the SN74AC533DWR is designed for surface mounting on printed circuit boards, facilitating efficient use of board space in compact electronic assemblies. Its robust design ensures high durability and long operational life, making it a reliable choice for designers and engineers looking to incorporate a dependable flip-flop logic device into their applications.

Overall, the SN74AC533DWR from Texas Instruments represents a blend of performance, flexibility, and quality, making it a preferred choice for digital logic applications that require precise control of data.