ON Semiconductor
Bild kan vara representation.
Se specifikationer för produktinformation.
MM74HC4020N
Visa detalj Datablad

MM74HC4020N

Product Overview

  • Category: Integrated Circuit (IC)
  • Use: Binary Counter
  • Characteristics: High-speed operation, low power consumption
  • Package: DIP (Dual In-line Package)
  • Essence: 14-stage binary ripple counter
  • Packaging/Quantity: Tube packaging, 25 pieces per tube

Specifications

  • Supply Voltage: 2V to 6V
  • Operating Temperature Range: -55°C to +125°C
  • Maximum Clock Frequency: 50 MHz
  • Number of Stages: 14
  • Output Type: Buffered
  • Propagation Delay: 13 ns (typical)

Detailed Pin Configuration

The MM74HC4020N has a total of 16 pins. Here is the detailed pin configuration:

  1. Pin 1: Clock Input (CP)
  2. Pin 2: Reset Input (MR)
  3. Pin 3: Output Q12
  4. Pin 4: Output Q5
  5. Pin 5: Output Q6
  6. Pin 6: Output Q7
  7. Pin 7: Output Q8
  8. Pin 8: Output Q9
  9. Pin 9: Output Q11
  10. Pin 10: Output Q10
  11. Pin 11: Output Q13
  12. Pin 12: Output Q14
  13. Pin 13: Ground (GND)
  14. Pin 14: Output Q4
  15. Pin 15: Output Q3
  16. Pin 16: VCC (Positive Power Supply)

Functional Features

  • The MM74HC4020N is a high-speed binary ripple counter.
  • It can count up to 2^14 (16,384) states.
  • The counter advances on the rising edge of the clock signal.
  • It has a synchronous reset input (MR) to clear the counter.
  • The outputs are buffered for enhanced driving capability.

Advantages and Disadvantages

Advantages: - High-speed operation allows for quick counting. - Low power consumption makes it energy-efficient. - Buffered outputs provide improved signal integrity. - Synchronous reset input enables easy counter clearing.

Disadvantages: - Limited number of stages may not be suitable for applications requiring higher counts. - Propagation delay of 13 ns may introduce timing issues in certain high-speed applications.

Working Principles

The MM74HC4020N operates as a binary ripple counter. It counts the number of clock pulses received and advances its internal state accordingly. The counter can be reset using the synchronous reset input (MR). The buffered outputs provide reliable signals for further processing or display.

Detailed Application Field Plans

The MM74HC4020N is commonly used in various applications, including:

  1. Frequency Division: The counter can divide an input frequency by a factor of 2^14, allowing for frequency scaling in electronic circuits.
  2. Time Delay Generation: By utilizing the propagation delay of the counter, precise time delays can be generated for controlling events in digital systems.
  3. Event Counting: The MM74HC4020N can be used to count events or pulses in applications such as industrial automation, robotics, and digital communication systems.

Detailed and Complete Alternative Models

Here are some alternative models that offer similar functionality:

  1. CD4020BE: This IC from Texas Instruments provides a 14-stage binary ripple counter with buffered outputs.
  2. SN74HC4040N: Another option from Texas Instruments, this IC offers a 12-stage binary ripple counter with buffered outputs.
  3. MC14020B: Manufactured by ON Semiconductor, this IC is a 14-stage binary counter with buffered outputs.

These alternative models can be considered based on specific requirements and availability.

(Note: The word count of this response is 347 words)

Lista 10 Vanliga frågor och svar relaterade till tillämpningen av MM74HC4020N i tekniska lösningar

Sure! Here are 10 common questions and answers related to the application of MM74HC4020N in technical solutions:

  1. Q: What is MM74HC4020N? A: MM74HC4020N is a 14-stage binary ripple counter with an integrated oscillator, commonly used in digital electronics.

  2. Q: What is the maximum clock frequency supported by MM74HC4020N? A: The maximum clock frequency supported by MM74HC4020N is typically around 25 MHz.

  3. Q: How many stages does MM74HC4020N have? A: MM74HC4020N has 14 stages, which means it can count up to 2^14 (16,384) different states.

  4. Q: Can MM74HC4020N be used as a frequency divider? A: Yes, MM74HC4020N can be used as a frequency divider by connecting the output of one stage to the input of the next stage.

  5. Q: What is the power supply voltage range for MM74HC4020N? A: The power supply voltage range for MM74HC4020N is typically between 2V and 6V.

  6. Q: Does MM74HC4020N have any built-in oscillator circuitry? A: Yes, MM74HC4020N has an integrated oscillator circuit that can be used to generate the clock signal.

  7. Q: Can MM74HC4020N be cascaded to increase the number of stages? A: Yes, multiple MM74HC4020N chips can be cascaded together to increase the number of stages and achieve higher counting ranges.

  8. Q: What is the typical propagation delay of MM74HC4020N? A: The typical propagation delay of MM74HC4020N is around 20 ns.

  9. Q: Can MM74HC4020N be used in both synchronous and asynchronous counting modes? A: Yes, MM74HC4020N can be used in both synchronous and asynchronous counting modes, depending on the application requirements.

  10. Q: What are some common applications of MM74HC4020N? A: MM74HC4020N is commonly used in applications such as frequency division, time measurement, event counting, and digital clocks.

Please note that the answers provided here are general and may vary depending on specific datasheet specifications and application requirements.