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MM74HCT74MX

MM74HCT74MX

Product Overview

  • Category: Integrated Circuit (IC)
  • Use: Flip-Flop
  • Characteristics: High-Speed, CMOS Logic, Dual D-Type Positive Edge-Triggered Flip-Flop
  • Package: 14-Pin SOIC (Small Outline Integrated Circuit)
  • Essence: The MM74HCT74MX is a versatile flip-flop IC that can store and transfer binary data. It is widely used in digital electronics for various applications.
  • Packaging/Quantity: Available in reels of 2500 units or tubes of 50 units.

Specifications

The MM74HCT74MX has the following specifications:

  • Supply Voltage Range: 2V to 6V
  • High-Level Input Voltage: 3.15V (minimum), 5.25V (maximum)
  • Low-Level Input Voltage: 0.9V (minimum), 1.35V (maximum)
  • High-Level Output Voltage: 4.4V (minimum), VCC (maximum)
  • Low-Level Output Voltage: 0.55V (maximum)
  • Maximum Operating Frequency: 33 MHz
  • Propagation Delay Time: 18 ns (maximum)
  • Power Dissipation: 500 mW (maximum)

Pin Configuration

The MM74HCT74MX has a 14-pin configuration as follows:

+---+--+---+ CLR -|1 +--+ 14|- VCC D1 -|2 13|- Q1 CLK -|3 12|- Q1' D2 -|4 11|- Q2' GND -|5 10|- Q2 PRN -|6 9|- CP PRP -|7 8|- CLR' +----------+

Functional Features

  • Dual D-Type Positive Edge-Triggered Flip-Flop: The MM74HCT74MX consists of two independent flip-flops that can be triggered by a positive edge of the clock signal.
  • Clear and Preset Inputs: The CLR (Clear) and PRN/PRP (Preset Negative/Positive) inputs allow for resetting or presetting the flip-flop outputs to specific states.
  • Complementary Outputs: The Q and Q' outputs provide complementary binary values, allowing for various logical operations.
  • High-Speed Operation: The MM74HCT74MX operates at high frequencies, making it suitable for time-critical applications.

Advantages and Disadvantages

Advantages: - Versatile functionality with dual flip-flops - Wide supply voltage range - High-speed operation - Compact SOIC package for space-saving designs

Disadvantages: - Limited maximum operating frequency compared to some other flip-flop ICs - Requires external components for proper operation

Working Principles

The MM74HCT74MX operates based on positive-edge triggering. When the CLK (Clock) input receives a rising edge, the data present at the D1 and D2 inputs are transferred to the Q1 and Q2 outputs, respectively. The CLR input can be used to clear the outputs, while the PRN/PRP inputs allow for presetting the outputs to desired states.

Detailed Application Field Plans

The MM74HCT74MX is commonly used in various digital electronic systems, including:

  1. Sequential Logic Circuits: It is widely employed in designing counters, shift registers, and other sequential logic circuits due to its flip-flop functionality.
  2. Data Storage Systems: The MM74HCT74MX can be utilized in memory units and data storage systems where reliable data retention and transfer are crucial.
  3. Clock Synchronization: It is used in clock synchronization circuits to ensure proper timing and synchronization of various components within a system.
  4. Digital Communication Systems: The MM74HCT74MX finds applications in digital communication systems, such as UART (Universal Asynchronous Receiver-Transmitter) interfaces, where data buffering and synchronization are required.

Detailed and Complete Alternative Models

  1. SN74HCT74: This is a similar flip-flop IC manufactured by Texas Instruments. It offers comparable functionality and specifications to the MM74HCT74MX.
  2. CD4013B: This dual D-type flip-flop IC from Texas Instruments operates at higher frequencies and provides additional features like Schmitt-trigger inputs.
  3. 74HC74: This dual positive-edge-triggered flip-flop IC from NXP Semiconductors is compatible with a wide range of supply voltages and offers high-speed operation.

(Note: These alternative models are provided for reference purposes and may have different pin configurations and specifications. Always refer to the respective datasheets for accurate information.)

In conclusion, the MM74HCT74MX is a versatile flip-flop

Énumérez 10 questions et réponses courantes liées à l'application de MM74HCT74MX dans les solutions techniques

Sure! Here are 10 common questions and answers related to the application of MM74HCT74MX in technical solutions:

  1. Question: What is MM74HCT74MX?
    - Answer: MM74HCT74MX is a dual D-type flip-flop integrated circuit (IC) that can store one bit of data.

  2. Question: What is the operating voltage range for MM74HCT74MX?
    - Answer: The operating voltage range for MM74HCT74MX is typically between 4.5V and 5.5V.

  3. Question: What is the maximum clock frequency supported by MM74HCT74MX?
    - Answer: MM74HCT74MX can support clock frequencies up to 25 MHz.

  4. Question: Can MM74HCT74MX be used as a counter?
    - Answer: Yes, MM74HCT74MX can be used as a basic counter by connecting multiple flip-flops together.

  5. Question: How many inputs and outputs does MM74HCT74MX have?
    - Answer: MM74HCT74MX has two inputs (D and CLK) and two outputs (Q and Q̅).

  6. Question: What is the power consumption of MM74HCT74MX?
    - Answer: The power consumption of MM74HCT74MX is relatively low, making it suitable for battery-powered applications.

  7. Question: Can MM74HCT74MX be used in both digital and analog circuits?
    - Answer: No, MM74HCT74MX is specifically designed for digital circuits and is not suitable for analog applications.

  8. Question: Is MM74HCT74MX compatible with other logic families?
    - Answer: Yes, MM74HCT74MX is compatible with other logic families such as TTL (Transistor-Transistor Logic) and CMOS (Complementary Metal-Oxide-Semiconductor).

  9. Question: What is the typical propagation delay of MM74HCT74MX?
    - Answer: The typical propagation delay of MM74HCT74MX is around 15 ns.

  10. Question: Can MM74HCT74MX be used in high-speed applications?
    - Answer: While MM74HCT74MX can operate at relatively high clock frequencies, it may not be suitable for extremely high-speed applications due to its limited speed compared to some other ICs.

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