The 74LVC2G74DP,125 from Nexperia is a dual positive-edge triggered D-type flip-flop. This device provides two independent flip-flops, each capable of storing a single bit of data. It is designed for low-voltage operation and high-speed performance, making it suitable for various digital logic applications.

Applications:

• Data storage
• Shift registers
• Frequency dividers
• Control circuits
• Delay lines

Features:

• Dual D-type flip-flops
• Positive-edge triggered
• Schmitt-trigger action at data input for high noise immunity
• Wide supply voltage range: 1.65 V to 5.5 V
• High-speed operation: tpd = 3.8 ns (typical) at 3.3 V
• Low power consumption
• Direct clear input
• CMOS technology

Benefits:

• Provides reliable data storage in various digital systems.
• Offers high noise immunity, ensuring stable operation in noisy environments.
• Facilitates fast and efficient data processing due to its high-speed performance.
• Reduces power consumption, making it suitable for battery-powered applications.
• Enables direct clearing of the flip-flop, simplifying system control.
• Compact design saves board space and reduces component count.

Additional Details:

The 74LVC2G74DP,125 is available in a space-saving PicoGate package. Each flip-flop has a data input (D), a clock input (CP), and a direct clear input (CD). The output (Q) reflects the data input at the rising edge of the clock pulse. The clear input overrides the clock and data inputs, setting the output low. This device is ideal for applications requiring reliable data storage, high-speed operation, and low power consumption. Its small size and comprehensive features make it a versatile solution for various digital logic applications. The Schmitt-trigger action on the data input ensures reliable operation even with slow or noisy input signals. The device's wide supply voltage range allows it to be used in a variety of systems with different voltage levels. The 74LVC2G74DP,125 is a cost-effective and efficient solution for implementing flip-flop functionality in digital circuits.