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74AHC1G126GW,125
Basic Information Overview
- Category: Integrated Circuit (IC)
- Use: Logic Gate Buffer/Driver
- Characteristics:
- High-speed CMOS technology
- Low power consumption
- Wide operating voltage range
- Schmitt-trigger input
- Package: SOT753 (SC-70-5)
- Essence: Single bus buffer with tri-state output
- Packaging/Quantity: Tape and Reel, 3000 pieces per reel
Specifications
- Supply Voltage Range: 2.0V to 5.5V
- Input Voltage Range: GND to VCC
- Output Voltage Range: GND to VCC
- Operating Temperature Range: -40°C to +125°C
- Output Drive Capability: ±24mA at VCC = 3.0V
- Propagation Delay: 4.5ns at VCC = 5.0V, CL = 15pF
Detailed Pin Configuration
The 74AHC1G126GW,125 IC has the following pin configuration:
____
OE |1 5| VCC
A |2 4| Y
GND |3 6| NC
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Functional Features
- Single gate buffer with tri-state output
- Output can be disabled using the OE (Output Enable) pin
- Schmitt-trigger input allows for better noise immunity
- Provides buffering and driving capability for a single bus line
Advantages
- High-speed operation due to advanced CMOS technology
- Low power consumption, making it suitable for battery-powered devices
- Wide operating voltage range allows compatibility with various systems
- Schmitt-trigger input ensures reliable operation in noisy environments
Disadvantages
- Limited output drive capability compared to some other ICs
- Only a single gate per package, limiting the number of buffers in a single IC
Working Principles
The 74AHC1G126GW,125 is a logic gate buffer with a tri-state output. It takes an input signal and amplifies it to drive the output line. The Schmitt-trigger input ensures that the input signal is properly interpreted, even in the presence of noise. The OE pin allows the output to be disabled when necessary.
Detailed Application Field Plans
The 74AHC1G126GW,125 can be used in various applications, including: - Data communication systems - Industrial automation - Consumer electronics - Automotive electronics - Medical devices
Detailed and Complete Alternative Models
Some alternative models that provide similar functionality are: - SN74LVC1G126DBVR (Texas Instruments) - MC74VHC1G126DF1G (ON Semiconductor) - NCV4266D2R2G (ON Semiconductor) - MM74HC126MTCX (Fairchild Semiconductor)
Please note that the above list is not exhaustive, and there may be other alternative models available from different manufacturers.
This concludes the encyclopedia entry for the 74AHC1G126GW,125 IC.
Sebutkan 10 pertanyaan dan jawaban umum terkait penerapan 74AHC1G126GW,125 dalam solusi teknis
Sure! Here are 10 common questions and answers related to the application of 74AHC1G126GW,125 in technical solutions:
Q1: What is the function of the 74AHC1G126GW,125? A1: The 74AHC1G126GW,125 is a single bus buffer gate with 3-state output. It is used to control the flow of data between different parts of a circuit.
Q2: What is the operating voltage range for the 74AHC1G126GW,125? A2: The operating voltage range for the 74AHC1G126GW,125 is typically between 2.0V and 5.5V.
Q3: How many inputs does the 74AHC1G126GW,125 have? A3: The 74AHC1G126GW,125 has one input.
Q4: How many outputs does the 74AHC1G126GW,125 have? A4: The 74AHC1G126GW,125 has one output.
Q5: What is the maximum output current of the 74AHC1G126GW,125? A5: The maximum output current of the 74AHC1G126GW,125 is typically 8mA.
Q6: Can the 74AHC1G126GW,125 be used in high-speed applications? A6: Yes, the 74AHC1G126GW,125 is designed for high-speed applications and has a propagation delay of typically 4.5ns.
Q7: Is the 74AHC1G126GW,125 compatible with other logic families? A7: Yes, the 74AHC1G126GW,125 is compatible with both CMOS and TTL logic families.
Q8: Can the 74AHC1G126GW,125 be used in both input and output applications? A8: Yes, the 74AHC1G126GW,125 can be used as both an input buffer and an output driver.
Q9: What is the package type of the 74AHC1G126GW,125? A9: The 74AHC1G126GW,125 is available in a small SOT353 package.
Q10: Are there any special considerations when using the 74AHC1G126GW,125 in a circuit? A10: It is important to ensure that the power supply voltage does not exceed the specified maximum voltage range, and that the input and output voltages are within the acceptable logic levels for the device. Additionally, proper decoupling capacitors should be used to minimize noise and ensure stable operation.
Please note that the answers provided here are general and may vary depending on specific datasheet specifications or application requirements.