Product Overview: 74AHC1G79GV by NXP Semiconductors

The 74AHC1G79GV is a high-speed Si-gate CMOS device from NXP Semiconductors, renowned for its reliability and performance in a wide array of digital applications. This particular product is a single positive-edge triggered D-type flip-flop with a clear input, designed to be a versatile component in modern electronic systems.

With its advanced 5V tolerant inputs, the 74AHC1G79GV is compatible with TTL levels, making it a suitable choice for interfacing with legacy systems or mixed-voltage environments. The device features an output capability of driving up to 8 LSTTL loads, providing the necessary drive strength for most applications.

Key Features

• Logic Type: D-Type Flip-Flop
• Propagation Delay Time: The device boasts a fast propagation delay, ensuring quick response times for critical applications.
• Operating Voltage Range: 2.0V to 5.5V, accommodating a variety of power supply requirements.
• High Noise Immunity: Possesses an inherent immunity to noise, which is crucial for stable operation in electrically noisy environments.
• Low Power Consumption: Designed for low power consumption, making it ideal for battery-operated and power-sensitive applications.
• Temperature Range: Operational over a broad temperature range, from -40°C to +125°C, suitable for industrial and automotive applications.

Package and Mounting

The 74AHC1G79GV is available in a very small and leadless SOT886 (VFQFN) package, which occupies minimal space on a printed circuit board (PCB). This package is optimized for surface-mount technology (SMT), enabling compact and high-density PCB designs.

Applications

Given its high-speed performance and robustness, the 74AHC1G79GV is an excellent choice for a multitude of applications, including:

• Control and logic systems
• Data storage and retrieval
• Counters and dividers
• Registers and multiplexers
• Clock domain synchronization

With its combination of features, the NXP 74AHC1G79GV represents a reliable and versatile solution for designers looking to implement flip-flops in their digital logic circuits.