Product Overview: 74LVC2G74GM from NXP

The 74LVC2G74GM is a high-performance, dual positive-edge triggered D-type flip-flop with individual data inputs (D), clock inputs (CP), master reset inputs (MR), and outputs (Q and Q̅). Manufactured by NXP Semiconductors, a leader in the electronics industry, this integrated circuit is part of the LVC (Low-Voltage CMOS) family, designed to operate with a power supply range of 1.65V to 5.5V.

This device is optimized for use in controlling and processing digital data in a wide array of applications, from consumer electronics to complex computing systems. The low voltage operation of the 74LVC2G74GM makes it suitable for battery-operated devices, and its high-speed performance is ideal for fast data processing tasks.

Key Features

• Low Power Consumption: The 74LVC2G74GM is designed for low power consumption, which is critical for extending battery life in portable applications.
• High-Speed Operation: With its capability to support high-frequency clock input, it is well-suited for high-speed data processing and communication systems.
• Wide Voltage Range: The device operates across a wide voltage range, from 1.65V to 5.5V, providing design flexibility for various system voltages.
• Input and Output Compatibility: Inputs are compatible with 5V logic levels, and the outputs can drive 5V inputs, making the device suitable for mixed-voltage applications.
• Multiple Package Options: Available in a compact DHVQFN14 package, the 74LVC2G74GM saves space on printed circuit boards.

Applications

• Portable and battery-powered devices
• Computers and computer peripherals
• Communication infrastructure
• Data storage and logic systems
• Industrial control systems

With its robust design and compatibility with multiple logic standards, the 74LVC2G74GM from NXP is a versatile choice for designers looking to incorporate reliable flip-flops into their digital systems. Its compact form factor and low power requirements make it an excellent choice for space-constrained applications that require efficient power management without compromising on performance.