The 74LVC74ADB 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). Designed and manufactured by NXP Semiconductors, a leader in the industry, this integrated circuit is part of the LVC family which operates on a low-voltage and high-speed CMOS technology.

Key Features

• Low Voltage Operation: The device is optimized for use in systems that require low power consumption, operating at a voltage range of 1.2V to 3.6V, making it ideal for battery-operated and portable applications.
• High Speed: It offers a propagation delay (t_pd) of just 3.7ns at a 3.3V supply voltage, allowing for high-speed operations which are crucial in modern digital systems.
• 5V Tolerant Inputs: The inputs can tolerate a 5V input level even when the device is operating at a lower voltage, providing compatibility with older 5V logic levels without the need for level shifters.
• Low Power Dissipation: It has an extremely low static power consumption, with a typical I_CC of only 10μA, significantly reducing the overall power requirements of the system.
• Output Drive Capability: The 74LVC74ADB can drive up to 50mA at the output, allowing for direct drive of LEDs and other high-drive components without additional buffering.
• Latch-up Performance: The device exceeds 100mA per JESD 78, Class II, ensuring stable operation even under stressful conditions.

Applications

With its robust performance characteristics, the 74LVC74ADB is suitable for a wide range of applications including:

• High-speed data processing
• Portable electronics
• Computing and storage systems
• Telecommunications
• Industrial control systems

Quality and Reliability

NXP Semiconductors is committed to delivering products of the highest quality and reliability. The 74LVC74ADB is no exception, undergoing rigorous testing and quality control measures to ensure it meets the industry's stringent standards. It is offered in a SO14 package, providing a compact solution for space-constrained applications.