The SN74AUP1G80DCKRE4 is a single positive-edge-triggered D-type flip-flop that operates on high-speed CMOS technology. It is designed to store a single bit of data and provide an output based on the clock input. The flip-flop has a clear input to reset the stored data.
Advantages: - High-speed operation - Wide supply voltage range - Small package size - Low power consumption
Disadvantages: - Limited number of inputs and outputs - Not suitable for complex logic operations
The SN74AUP1G80DCKRE4 operates by storing the state of the D input when a positive edge is detected on the CLK input. The stored data is then available at the Q output. The flip-flop can be cleared by applying a low signal to the clear input.
The SN74AUP1G80DCKRE4 is commonly used in various digital systems where the storage and retrieval of a single bit of data is required. Some specific application fields include:
These alternative models offer similar functionality and characteristics to the SN74AUP1G80DCKRE4, providing options for different package types or quantities.
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Sure! Here are 10 common questions and answers related to the application of SN74AUP1G80DCKRE4 in technical solutions:
Q1: What is the SN74AUP1G80DCKRE4? A1: The SN74AUP1G80DCKRE4 is a single positive-edge-triggered D-type flip-flop with preset and clear. It is a commonly used integrated circuit (IC) in digital electronics.
Q2: What is the voltage range supported by SN74AUP1G80DCKRE4? A2: The SN74AUP1G80DCKRE4 supports a voltage range from 0.8V to 3.6V, making it suitable for low-power applications.
Q3: How many inputs and outputs does SN74AUP1G80DCKRE4 have? A3: The SN74AUP1G80DCKRE4 has one data input (D), one clock input (CLK), one preset input (PRE), one clear input (CLR), and one output (Q).
Q4: What is the maximum operating frequency of SN74AUP1G80DCKRE4? A4: The maximum operating frequency of SN74AUP1G80DCKRE4 is typically around 500 MHz, depending on the specific conditions and setup.
Q5: Can SN74AUP1G80DCKRE4 be used in battery-powered devices? A5: Yes, SN74AUP1G80DCKRE4 is designed for low-power applications and can be used in battery-powered devices due to its wide voltage range and low power consumption.
Q6: What is the typical propagation delay of SN74AUP1G80DCKRE4? A6: The typical propagation delay of SN74AUP1G80DCKRE4 is around 2.5 ns, which means it takes approximately 2.5 nanoseconds for the output to respond to a change in the input.
Q7: Can SN74AUP1G80DCKRE4 be used in high-speed applications? A7: While SN74AUP1G80DCKRE4 has a relatively high operating frequency, it may not be suitable for very high-speed applications where faster flip-flops or latches are required.
Q8: What is the power supply voltage required for SN74AUP1G80DCKRE4? A8: SN74AUP1G80DCKRE4 requires a power supply voltage between 0.8V and 3.6V, making it compatible with various power supply configurations.
Q9: Can SN74AUP1G80DCKRE4 be cascaded to create larger flip-flop circuits? A9: Yes, multiple SN74AUP1G80DCKRE4 flip-flops can be cascaded together to create larger flip-flop circuits, allowing for more complex digital logic designs.
Q10: What are some typical applications of SN74AUP1G80DCKRE4? A10: SN74AUP1G80DCKRE4 can be used in various applications such as data storage, synchronization, clock division, and general-purpose digital logic circuits.
Please note that these answers are general and may vary depending on specific design requirements and conditions.