The SN74LVC2G79YEPR has the following pin configuration:
Advantages: - High-speed operation allows for efficient data processing - Low power consumption reduces energy usage - Wide supply voltage range provides flexibility in various applications - True and complementary outputs enable versatile circuit designs - Preset and clear inputs simplify initialization process
Disadvantages: - Limited number of flip-flops in a single package - Not suitable for applications requiring a higher clock frequency
The SN74LVC2G79YEPR is a dual positive edge-triggered D-type flip-flop. It operates based on the rising edge of the clock signal, capturing and storing the data input at that moment. The flip-flop can be preset or cleared asynchronously using the dedicated inputs. The true and complementary outputs provide both inverted and non-inverted versions of the stored data.
The SN74LVC2G79YEPR is commonly used in various digital systems and applications, including:
These alternative models offer similar functionality and characteristics to the SN74LVC2G79YEPR, providing options for different package preferences or specific application requirements.
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Sure! Here are 10 common questions and answers related to the application of SN74LVC2G79YEPR in technical solutions:
Q: What is the SN74LVC2G79YEPR? A: The SN74LVC2G79YEPR is a dual positive-edge-triggered D-type flip-flop with set and reset functionality.
Q: What is the operating voltage range of SN74LVC2G79YEPR? A: The operating voltage range of SN74LVC2G79YEPR is from 1.65V to 5.5V.
Q: What is the maximum clock frequency supported by SN74LVC2G79YEPR? A: The maximum clock frequency supported by SN74LVC2G79YEPR is typically 100 MHz.
Q: Can SN74LVC2G79YEPR be used in battery-powered applications? A: Yes, SN74LVC2G79YEPR can be used in battery-powered applications as it operates at low voltages.
Q: Does SN74LVC2G79YEPR have internal pull-up or pull-down resistors? A: No, SN74LVC2G79YEPR does not have internal pull-up or pull-down resistors.
Q: What is the typical propagation delay of SN74LVC2G79YEPR? A: The typical propagation delay of SN74LVC2G79YEPR is around 3.8 ns.
Q: Can SN74LVC2G79YEPR be used in high-speed data transfer applications? A: Yes, SN74LVC2G79YEPR can be used in high-speed data transfer applications due to its fast propagation delay.
Q: What is the power supply current consumption of SN74LVC2G79YEPR? A: The power supply current consumption of SN74LVC2G79YEPR is typically around 1.5 mA.
Q: Can SN74LVC2G79YEPR be used in automotive applications? A: Yes, SN74LVC2G79YEPR can be used in automotive applications as it has a wide operating voltage range and is compatible with automotive standards.
Q: Does SN74LVC2G79YEPR have any special features for noise reduction? A: Yes, SN74LVC2G79YEPR has hysteresis on the clock input to improve noise immunity.
Please note that these answers are general and may vary depending on specific application requirements. It's always recommended to refer to the datasheet and consult with technical experts for accurate information.