CD74AC175M Quad D-Type Flip-Flop by Texas Instruments

The CD74AC175M is a high-speed CMOS logic Quad D-Type Flip-Flop integrated circuit, designed and manufactured by the renowned electronics company Texas Instruments (TI). This device features four individual D-type flip-flops with direct clear inputs, making it an essential component for a variety of digital applications where the storage or transfer of data is required.

Each flip-flop has independent data ('D'), clock ('CLK'), and clear ('CLR') inputs, with the outputs being the normal 'Q' and the complement 'Q̅'. The flip-flops are positive-edge triggered, meaning that the data on the 'D' input is accepted and transferred to the 'Q' output on the rising edge of the clock pulse, providing a reliable and predictable timing mechanism for digital circuits.

The CD74AC175M operates with a wide supply voltage range from 1.5V to 5.5V, which allows it to be used in various systems with different power levels. This versatility makes it suitable for interfacing with both standard CMOS and Low Power Schottky TTL logic levels. With its fast switching speeds and low power consumption, this flip-flop is ideal for use in high-speed data processing systems, computers, instrumentation, and control systems.

Moreover, the CD74AC175M is characterized for operation from -55°C to 125°C, ensuring reliable performance over a wide temperature range, which is crucial for applications in harsh environments. The device comes in a surface-mount SOIC-16 package, which is compact and suitable for high-density mounting on printed circuit boards.

Key features of the CD74AC175M include:

• High-speed CMOS technology
• Quad D-type flip-flops with direct clear
• Wide operating voltage range (1.5V to 5.5V)
• Compatibility with TTL logic levels
• Low power consumption
• Positive-edge trigger
• Wide operating temperature range (-55°C to 125°C)
• Surface-mount SOIC-16 package

With its robust features and TI's reputation for quality, the CD74AC175M is a reliable choice for designers and engineers looking to implement flip-flops in their digital logic systems.