Overview of N74ALS374D from NXP

The N74ALS374D is a high-performance integrated circuit from NXP Semiconductors, designed for use in a wide range of digital applications. This device is part of the Advanced Low-Power Schottky (ALS) family, which is renowned for combining low power consumption with high-speed operation and improved output drive capabilities.

Key Features

• Octal D-Type Flip-Flop: The N74ALS374D features eight edge-triggered D-type flip-flops, making it ideal for applications that require the storage and transfer of 8-bit data.
• 3-State Outputs: Each flip-flop has a 3-state output that can be used in bus-oriented applications. This allows for efficient data flow control and bus sharing without the need for external multiplexing circuitry.
• Positive-Edge Triggering: The flip-flops are triggered on the positive-going edge of the clock pulse, ensuring reliable timing and synchronization with other system components.
• Direct Clear Input: A direct clear input is provided for each flip-flop, allowing for asynchronous clearing of the flip-flop's contents, which is useful for system initialization or error recovery processes.

Electrical Characteristics

• Supply Voltage Range: The device operates over a wide supply voltage range, accommodating different system power requirements.
• Low Power Consumption: As part of the ALS series, the N74ALS374D boasts low power consumption, making it suitable for power-sensitive applications.
• High-Speed Performance: Despite its low power usage, the N74ALS374D does not compromise on speed, offering high-speed operation that can meet the demands of fast digital systems.

Applications

The N74ALS374D is versatile and can be used in a variety of digital systems, including:

• Computer systems
• Data storage devices
• Communication systems
• Control systems
• Industrial automation

With its robust feature set and reliable performance, the N74ALS374D from NXP Semiconductors is an excellent choice for designers looking to implement efficient data storage and transfer mechanisms in their digital applications.