ON Semiconductor MC10198 - High-Speed Dual Type D Flip-Flop

The ON Semiconductor MC10198 is a versatile, high-speed dual type D flip-flop integrated circuit designed for use in advanced digital systems. This device features two independent flip-flops with common clock and reset inputs, making it an ideal choice for applications requiring synchronous data transfer and storage.

Key Features:

• High-Speed Performance: The MC10198 is capable of operating at high clock frequencies, ensuring rapid and reliable data transfer, which is crucial for high-speed digital applications.
• Dual Flip-Flops: With two flip-flops in one package, this IC allows for compact and efficient design layouts, saving space on printed circuit boards.
• Common Clock and Reset: Simplified system design is achieved through common clock and master reset inputs, which provide synchronous control over both flip-flops.
• Asynchronous Master Reset: The asynchronous master reset feature allows for immediate resetting of the flip-flop outputs to the low state, regardless of the clock signal.
• Differential Outputs: The MC10198 offers differential outputs, which provide improved noise immunity and the ability to drive balanced loads.
• Power Efficiency: Designed with power efficiency in mind, this IC minimizes power consumption, making it suitable for power-sensitive applications.

Applications:

The ON Semiconductor MC10198 is well-suited for a wide range of applications, including but not limited to:

• High-speed data processing systems
• Communication systems
• Digital signal processing (DSP)
• Instrumentation and control systems
• Frequency dividers and counters

Product Specifications:

The MC10198 is offered in a compact package and is characterized by the following specifications:

• Supply Voltage: 4.5V to 5.5V
• Operating Temperature: -55°C to +125°C
• Propagation Delay Time: Typically 1.5 ns

With its high-speed performance and dual flip-flop configuration, the ON Semiconductor MC10198 is an excellent choice for designers looking to implement efficient and reliable digital logic circuits.