MC74HC374ADWG
- Created at: 2023-10-19 10:58:11 , by WikiIC
- Updated at: 2023-10-19 10:58:11
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MC74HC374ADWG
Product Overview
Category
MC74HC374ADWG belongs to the category of integrated circuits (ICs).
Use
This product is commonly used in digital electronics and microprocessor-based systems.
Characteristics
- High-speed operation
- Low power consumption
- Compatibility with TTL inputs
- Wide operating voltage range
Package
MC74HC374ADWG is available in a DWG package.
Essence
The essence of MC74HC374ADWG lies in its ability to store and transfer data in digital systems.
Packaging/Quantity
This product is typically packaged in reels or tubes, with a quantity of 250 units per reel/tube.
Specifications
- Supply Voltage: 2V to 6V
- Input Voltage: 0V to VCC
- Output Voltage: 0V to VCC
- Operating Temperature Range: -40°C to +85°C
- Logic Family: HC
- Number of Flip-Flops: 8
Detailed Pin Configuration
- CP (Clock Pulse) - Clock input for storing and transferring data.
- D0-D7 (Data Inputs) - Inputs for data to be stored or transferred.
- OE (Output Enable) - Enables or disables the outputs.
- Q0-Q7 (Flip-Flop Outputs) - Outputs for stored or transferred data.
- GND (Ground) - Ground reference for the IC.
- VCC (Supply Voltage) - Power supply input for the IC.
Functional Features
MC74HC374ADWG is an octal D-type flip-flop with a common clock and output enable. It can store and transfer data on the rising edge of the clock signal. The output enable pin allows the user to control the output state of the flip-flops. When disabled, the outputs are in a high-impedance state.
Advantages and Disadvantages
Advantages
- High-speed operation allows for efficient data transfer.
- Low power consumption makes it suitable for battery-powered devices.
- Compatibility with TTL inputs ensures easy integration into existing systems.
- Wide operating voltage range provides flexibility in various applications.
Disadvantages
- Limited number of flip-flops (8) may not be sufficient for complex systems.
- Lack of built-in protection features against voltage spikes or ESD events.
Working Principles
MC74HC374ADWG operates based on the principles of digital logic. The clock pulse triggers the storage or transfer of data from the input pins to the flip-flops. The output enable pin controls the state of the outputs, allowing for selective output activation. The IC's internal circuitry ensures reliable data storage and transfer.
Detailed Application Field Plans
MC74HC374ADWG finds applications in various fields, including: 1. Microprocessor-based systems 2. Data storage and transfer systems 3. Communication equipment 4. Industrial automation 5. Automotive electronics
Detailed and Complete Alternative Models
Some alternative models that can be considered as alternatives to MC74HC374ADWG are: 1. SN74HC374N by Texas Instruments 2. CD74HC374E by Texas Instruments 3. 74HC374D by NXP Semiconductors 4. MM74HC374WM by Fairchild Semiconductor 5. MC74HCT374AN by ON Semiconductor
These alternative models offer similar functionality and can be used as replacements depending on specific requirements.
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List 10 common questions and answers related to the application of MC74HC374ADWG in technical solutions
Sure! Here are 10 common questions and answers related to the application of MC74HC374ADWG in technical solutions:
Q: What is MC74HC374ADWG? A: MC74HC374ADWG is a type of integrated circuit (IC) commonly used as an octal D-type flip-flop with three-state outputs.
Q: What are the typical applications of MC74HC374ADWG? A: MC74HC374ADWG is often used in digital systems for data storage, data transfer, and synchronization purposes.
Q: What is the operating voltage range of MC74HC374ADWG? A: The operating voltage range of MC74HC374ADWG is typically between 2V and 6V.
Q: How many flip-flops are there in MC74HC374ADWG? A: MC74HC374ADWG contains 8 flip-flops, making it an octal (8-bit) device.
Q: What is the maximum clock frequency supported by MC74HC374ADWG? A: The maximum clock frequency supported by MC74HC374ADWG is typically around 25 MHz.
Q: Can MC74HC374ADWG be used in both parallel and serial data transfer modes? A: Yes, MC74HC374ADWG can be used in both parallel and serial data transfer modes, depending on the configuration.
Q: Does MC74HC374ADWG have any built-in output enable functionality? A: Yes, MC74HC374ADWG has a built-in output enable pin that allows the user to control the output state.
Q: What is the power supply current consumption of MC74HC374ADWG? A: The power supply current consumption of MC74HC374ADWG is typically low, ranging from a few microamps to tens of milliamps.
Q: Can MC74HC374ADWG tolerate high-speed switching and noise immunity? A: Yes, MC74HC374ADWG has good noise immunity and can handle high-speed switching without significant issues.
Q: Are there any specific precautions to consider when using MC74HC374ADWG? A: It is important to ensure proper decoupling capacitors are used near the power supply pins to minimize noise and voltage fluctuations. Additionally, care should be taken to avoid exceeding the maximum ratings specified in the datasheet, such as voltage and temperature limits.
Please note that the answers provided here are general and may vary depending on the specific datasheet and manufacturer's recommendations for MC74HC374ADWG.
- https://chipmlcc.ru/product/details/on-semiconductor/mc74hc374adwg.html [PDF download, circuit diagram, pin configuration, detailed specifications, and more electronic component spot channels.]
- https://www.chipmlcc.com/product/details/on-semiconductor/mc74hc374adwg.html [PDF download, circuit diagram, pin configuration, detailed specifications, and more electronic component spot channels.]
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