MC74AC74NG
Product Overview
- Category: Integrated Circuit (IC)
- Use: Flip-Flop
- Characteristics: High-speed, low-power consumption
- Package: DIP (Dual In-line Package)
- Essence: Digital logic component for storing and transferring binary data
- Packaging/Quantity: 20 pieces per tube
Specifications
- Logic Family: AC
- Logic Type: D-Type Flip-Flop
- Number of Elements: 2
- Number of Bits per Element: 1
- Propagation Delay Time: 7 ns
- Operating Voltage Range: 2V to 6V
- Operating Temperature Range: -40°C to +85°C
Detailed Pin Configuration
The MC74AC74NG has a total of 14 pins. The pin configuration is as follows:
- CLR (Clear Input)
- D (Data Input)
- CLK (Clock Input)
- PR (Preset Input)
- Q (Output)
- Q̅ (Complementary Output)
- GND (Ground)
- Q̅ (Complementary Output)
- Q (Output)
- PR (Preset Input)
- CLK (Clock Input)
- D (Data Input)
- CLR (Clear Input)
- VCC (Positive Power Supply)
Functional Features
- Flip-Flop Operation: The MC74AC74NG operates as a positive-edge triggered D-type flip-flop.
- Data Storage: It can store one bit of binary data at a time.
- Data Transfer: The stored data can be transferred to the output upon receiving a clock signal.
- Clear and Preset Inputs: The flip-flop can be cleared or preset using the CLR and PR inputs, respectively.
Advantages and Disadvantages
Advantages: - High-speed operation - Low power consumption - Wide operating voltage range - Compact DIP package for easy integration
Disadvantages: - Limited number of flip-flops per IC (2 in this case) - Not suitable for high-frequency applications
Working Principles
The MC74AC74NG is based on positive-edge triggered flip-flop technology. It utilizes a clock signal to control the transfer of data from the input to the output. The CLR and PR inputs allow for clearing or presetting the flip-flop, respectively. The IC operates within a specified voltage and temperature range.
Detailed Application Field Plans
The MC74AC74NG can be used in various digital systems and applications, including but not limited to: - Counters and registers - Data storage and transfer circuits - Clock synchronization circuits - Control and timing circuits
Detailed and Complete Alternative Models
Some alternative models that offer similar functionality to the MC74AC74NG are: - SN74AC74N by Texas Instruments - CD74AC74E by Texas Instruments - 74HC74 by NXP Semiconductors - 74LS74 by Fairchild Semiconductor
These alternatives may have slight variations in specifications and pin configuration, but they serve the same purpose as the MC74AC74NG.
Word count: 314 words
기술 솔루션에 MC74AC74NG 적용과 관련된 10가지 일반적인 질문과 답변을 나열하세요.
Sure! Here are 10 common questions and answers related to the application of MC74AC74NG in technical solutions:
Q: What is MC74AC74NG? A: MC74AC74NG is a dual D-type flip-flop integrated circuit (IC) that can store one bit of data.
Q: What is the voltage range supported by MC74AC74NG? A: MC74AC74NG supports a voltage range of 2V to 6V.
Q: What is the maximum clock frequency for MC74AC74NG? A: The maximum clock frequency for MC74AC74NG is typically around 100 MHz.
Q: Can MC74AC74NG be used in both digital and analog circuits? A: No, MC74AC74NG is specifically designed for digital circuits and is not suitable for analog applications.
Q: How many inputs and outputs does MC74AC74NG have? A: MC74AC74NG has two inputs (D and CLK) and two outputs (Q and Q̅).
Q: What is the purpose of the CLR (clear) input in MC74AC74NG? A: The CLR input is used to reset the flip-flop and clear its stored data.
Q: Can MC74AC74NG operate in both synchronous and asynchronous modes? A: Yes, MC74AC74NG can operate in both synchronous and asynchronous modes, depending on the clock signal.
Q: What is the power supply requirement for MC74AC74NG? A: MC74AC74NG requires a single power supply voltage between 2V and 6V.
Q: Is MC74AC74NG suitable for high-speed applications? A: Yes, MC74AC74NG is designed for high-speed operation and can be used in applications that require fast data storage.
Q: Can MC74AC74NG be cascaded to create larger memory storage? A: Yes, multiple MC74AC74NG flip-flops can be cascaded together to create larger memory storage by connecting the Q output of one flip-flop to the D input of the next.