74LVC1G79GW,165

Basic Information Overview

Category: Integrated Circuit (IC)
Use: Logic Gate
Characteristics: Single Positive Edge-Triggered D-Type Flip-Flop
Package: SOT753
Essence: High-speed CMOS technology
Packaging/Quantity: Tape and Reel, 3000 pieces per reel

Specifications

Supply Voltage Range: 1.65V to 5.5V
Input Voltage Range: -0.5V to VCC + 0.5V
Output Voltage Range: GND to VCC
Operating Temperature Range: -40°C to +125°C
Propagation Delay: 4.3 ns (typical) at 2.7V
Maximum Quiescent Current: 10 µA at 5.5V

Detailed Pin Configuration

The 74LVC1G79GW,165 has a total of six pins: 1. Q: Output of the flip-flop 2. D: Data input 3. CP: Clock input 4. PR: Asynchronous preset input 5. CLR: Asynchronous clear input 6. GND: Ground

Functional Features

Single positive edge-triggered D-type flip-flop with reset and preset functionality
High-speed operation due to advanced CMOS technology
Low power consumption
Schmitt-trigger action on all inputs allows for noisy input environments
Balanced propagation delays between clock and data inputs

Advantages and Disadvantages

Advantages: - Compact size and low power consumption make it suitable for portable devices - Wide supply voltage range allows for compatibility with various systems - Schmitt-trigger action ensures reliable operation in noisy environments

Disadvantages: - Limited number of flip-flops in a single package - Not suitable for applications requiring multiple flip-flops

Working Principles

The 74LVC1G79GW,165 is a positive edge-triggered D-type flip-flop. It stores and outputs data based on the rising edge of the clock signal. The flip-flop can be asynchronously reset or preset using the CLR and PR inputs, respectively. It operates using high-speed CMOS technology, providing fast and reliable performance.

Detailed Application Field Plans

The 74LVC1G79GW,165 can be used in various applications, including: - Digital communication systems - Data storage devices - Microcontrollers - Industrial automation - Consumer electronics

Detailed and Complete Alternative Models

Some alternative models to the 74LVC1G79GW,165 include: - SN74LVC1G79DBVR - MC74VHC1G79DTT1G - TC7SZ79FUTE85LF

These models offer similar functionality and characteristics, providing options for different design requirements.

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10個與74LVC1G79GW,165在技術方案中應用相關的常見問題與解答

Sure! Here are 10 common questions and answers related to the application of 74LVC1G79GW,165 in technical solutions:

Q1: What is the 74LVC1G79GW,165? A1: The 74LVC1G79GW,165 is a single positive-edge triggered D-type flip-flop with reset. It is commonly used in digital logic circuits.

Q2: What is the operating voltage range for the 74LVC1G79GW,165? A2: The operating voltage range for the 74LVC1G79GW,165 is typically between 1.65V and 5.5V.

Q3: How many inputs does the 74LVC1G79GW,165 have? A3: The 74LVC1G79GW,165 has two inputs - a data input (D) and a reset input (R).

Q4: What is the function of the reset input (R) in the 74LVC1G79GW,165? A4: The reset input (R) in the 74LVC1G79GW,165 is used to asynchronously reset the flip-flop, forcing its output to a known state.

Q5: What is the maximum clock frequency for the 74LVC1G79GW,165? A5: The maximum clock frequency for the 74LVC1G79GW,165 is typically around 200 MHz.

Q6: Can the 74LVC1G79GW,165 be used in both synchronous and asynchronous applications? A6: Yes, the 74LVC1G79GW,165 can be used in both synchronous and asynchronous applications, depending on the requirements of the circuit.

Q7: What is the typical propagation delay of the 74LVC1G79GW,165? A7: The typical propagation delay of the 74LVC1G79GW,165 is around 4.5 ns.

Q8: Can the 74LVC1G79GW,165 be used in high-speed applications? A8: Yes, the 74LVC1G79GW,165 is designed for high-speed operation and can be used in high-speed applications.

Q9: What is the package type for the 74LVC1G79GW,165? A9: The 74LVC1G79GW,165 is available in a small SOT-353 package.

Q10: Are there any special considerations when using the 74LVC1G79GW,165 in a circuit? A10: It is important to ensure that the power supply voltage is within the specified range and that the input signals meet the voltage level requirements of the flip-flop. Additionally, proper decoupling capacitors should be used to minimize noise and ensure stable operation.