SN74HC393N
Product Overview
- Category: Integrated Circuit
- Use: Binary Counter/Divider
- Characteristics:
- High-speed operation
- Wide operating voltage range
- Low power consumption
- Package: DIP (Dual In-line Package)
- Essence: Dual 4-bit binary ripple counter
- Packaging/Quantity: Tube/25 pieces
Specifications
- Supply Voltage Range: 2V to 6V
- Maximum Clock Frequency: 50 MHz
- Number of Counting Stages: 2
- Output Current: ±6 mA
- Operating Temperature Range: -40°C to +85°C
Detailed Pin Configuration
The SN74HC393N has a total of 14 pins, which are assigned as follows:
- Clock Input A (CPA)
- Clock Input B (CPB)
- Reset Input (MR)
- Data Input A (DA)
- Data Input B (DB)
- Carry Output A (COA)
- Carry Output B (COB)
- Q0 Output A (Q0A)
- Q1 Output A (Q1A)
- Q2 Output A (Q2A)
- Q3 Output A (Q3A)
- Q0 Output B (Q0B)
- Q1 Output B (Q1B)
- Q2 Output B (Q2B)
Functional Features
- Dual 4-bit binary ripple counter
- Asynchronous reset functionality
- Independent clock inputs for each counter
- Outputs can be used as clock inputs for cascading multiple counters
- Carry outputs for cascading counters
Advantages and Disadvantages
Advantages
- High-speed operation allows for efficient counting/dividing tasks
- Wide operating voltage range provides flexibility in various applications
- Low power consumption helps conserve energy
- Asynchronous reset feature allows for easy initialization
Disadvantages
- Limited number of counting stages (2 in this case)
- Output current is relatively low, limiting direct drive capabilities
Working Principles
The SN74HC393N is a dual 4-bit binary ripple counter that counts up or down depending on the clock inputs and data inputs. The counters operate asynchronously, meaning they can be reset independently of each other. The carry outputs enable cascading multiple counters to achieve higher bit counts.
Detailed Application Field Plans
The SN74HC393N is commonly used in various applications, including:
- Frequency division: Dividing high-frequency signals into lower frequencies.
- Event counting: Counting occurrences of specific events or pulses.
- Timekeeping: Tracking time intervals or durations.
- Digital displays: Driving LED or LCD displays for numeric output.
- Sequential control: Generating sequential patterns for controlling devices.
Detailed and Complete Alternative Models
Some alternative models to the SN74HC393N include:
- CD40193: Similar functionality with different package options.
- MC14093B: Quad 2-input NAND Schmitt trigger, which can be used as a counter/divider.
- 74LS393: Low-power Schottky version of the dual 4-bit binary counter.
These alternatives offer similar features and can be suitable replacements based on specific requirements.
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Lista 10 Vanliga frågor och svar relaterade till tillämpningen av SN74HC393N i tekniska lösningar
Sure! Here are 10 common questions and answers related to the application of SN74HC393N in technical solutions:
Q: What is SN74HC393N? A: SN74HC393N is a dual 4-bit binary ripple counter IC, commonly used in digital circuits for counting and frequency division applications.
Q: What is the operating voltage range of SN74HC393N? A: The operating voltage range of SN74HC393N is typically between 2V and 6V.
Q: What is the maximum clock frequency supported by SN74HC393N? A: SN74HC393N can support clock frequencies up to 25 MHz.
Q: How many outputs does SN74HC393N have? A: SN74HC393N has two independent 4-bit ripple counters, each with separate outputs.
Q: Can SN74HC393N be cascaded to increase the number of bits? A: Yes, multiple SN74HC393N ICs can be cascaded together to increase the number of bits in the counter.
Q: What is the power supply current requirement for SN74HC393N? A: The power supply current requirement for SN74HC393N is typically around 4 mA.
Q: Does SN74HC393N have any built-in reset functionality? A: No, SN74HC393N does not have a built-in reset function. External circuitry is required to reset the counter.
Q: Can SN74HC393N be used in both synchronous and asynchronous modes? A: Yes, SN74HC393N can be used in both synchronous and asynchronous modes, depending on the application requirements.
Q: What is the typical propagation delay of SN74HC393N? A: The typical propagation delay of SN74HC393N is around 15 ns.
Q: What are some common applications of SN74HC393N? A: SN74HC393N is commonly used in applications such as frequency division, event counting, time delay generation, and digital clocks.
Please note that the answers provided here are general and may vary depending on specific datasheet specifications and application requirements.