NXP USA Inc. 74LVC30APW118
The picture is for reference only, please refer to the product specification
- 74LVC30APW118
- NXP USA Inc.
- NAND GATE
- Logic - Gates and Inverters
- 74LVC30APW118 Datasheet
- -
- Bulk
-
Lead free / RoHS Compliant - 2161
- Spot Inventory / Athorized Dstributor / Factory Excess Stock
- 1 year quality assurance 》
- Click to get rates
What is 74LVC30APW118
NXP USA Inc. Part Number 74LVC30APW118(Logic - Gates and Inverters), developed and manufactured by NXP USA Inc., distributed globally by Jinftry. We distribute various electronic components from world-renowned brands and provide one-stop services, making us a trusted global electronic component distributor.
74LVC30APW118 is one of the part numbers distributed by Jinftry, and you can learn about its specifications/configurations, package/case, Datasheet, and other information here. Electronic components are affected by supply and demand, and prices fluctuate frequently. If you have a demand, please do not hesitate to send us an RFQ or email us immediately [email protected] Please inquire about the real-time unit price, Data Code, Lead time, payment terms, and any other information you would like to know. We will do our best to provide you with a quotation and reply as soon as possible.
74LVC30APW118 Specifications
- Part Number74LVC30APW118
- CategoryLogic - Gates and Inverters
- ManufacturerNXP USA Inc.
- DescriptionNAND GATE
- PackageBulk
- Series-
- Features-
- Voltage - Supply-
- Operating Temperature-
- Mounting Type-
- Package / Case-
- Supplier Device Package-
- Number of Circuits-
- Number of Inputs-
- Current - Output High, Low-
- Current - Quiescent (Max)-
- Logic Type-
- Max Propagation Delay @ V, Max CL-
- Logic Level - Low-
- Logic Level - High-
Application of 74LVC30APW118
74LVC30APW118 Datasheet
74LVC30APW118 Datasheet , Bulk
74LVC30APW118 Classification
Logic - Gates and Inverters
FAQ about Logic - Gates and Inverters
-
1. What is a logic gate in an IC?
A logic gate in an IC is an electronic component used to perform logic operations. Logic gates are often used to implement basic logic functions such as AND, OR, NOT, etc., and are the basic building blocks in digital circuits.
The working principle of the logic gate is based on the properties of semiconductor materials, especially PN junctions. When a voltage is applied between the source and the drain, current will not flow through this barrier without a gate voltage. However, when an appropriate voltage is applied to the gate, it changes the electric field distribution at the PN junction, allowing current to pass. In short, the gate voltage controls the flow of current from the source to the drain, which enables the transistor to be used as a switch: closed when there is no gate voltage and open when there is a gate voltage.
In integrated circuits (ICs), logic gates usually refer to field effect transistors (FETs) or metal oxide semiconductor field effect transistors (MOSFETs). These transistors have three terminals: source, drain, and gate. The source and drain are the entrance and exit of the current, while the gate is used to control the flow of current. By controlling the gate voltage, the switching control of the current in the circuit can be achieved, thereby performing various logical operations. -
2. Why is it called an inverter?
The name inverter comes from its working principle of converting direct current into alternating current, that is, "reversing" the operation of the rectifier. The inverter was originally called an "inverter" because it converts direct current into alternating current, which is the opposite of the working principle of the rectifier.
The definition and basic function of the inverter is to convert direct current power into alternating current. It is a device that converts the power of a DC power source such as a battery or storage battery into alternating current power for use by various devices that require AC power.
The history of the inverter also reflects the origin of its name. Early inverters were devices that converted AC to DC, while modern inverters reversed the process and converted DC to AC. With the development of technology, inverters have changed from mechanical devices to devices with solid-state circuits, becoming an important part of the field of power electronics. -
3. Can NAND gates be used as inverters?
NAND gates can be used as inverters. NAND gates, especially Schmitt-triggered NAND gates, are often used in full-bridge inverter circuits to ensure that the switch between the two channels is clear and not affected by any type of stray transients or low-signal interference.
In the inverter, the role of the NAND gate is to drive the MOSFET or IGBT through logic control to achieve DC to AC conversion. For example, in the Arduino-based full-bridge sine wave inverter design, the Arduino is programmed to generate SPWM outputs in the appropriate format from the pins, process these signals through the NAND gate, and finally drive the relevant MOSFETs of the full-bridge driver network to achieve the inverter function.
The advantages of using NAND gates include fast switching response and high reliability. In addition, Schmitt-triggered NAND gates can enhance anti-interference capabilities and ensure stable operation of the inverter. However, there are also challenges to consider when designing inverters, such as switching losses and thermal management.
We are a professional PCB manufacturer who offers comprehensive PCB manufacturing services including: professional Ceramic PCB HDI PCB Heavy Copper PCB High-TG PCB High Speed PCB High Frequency PCB Metal Core PCB PCB fabrication and PCB assembly, providing fast turnaround prototypes for high-end products.
• Prompt Responsiveness
• Guaranteed Quality
• Global Access
• Competitive Market Price
• One-Stop support services of supply chain
Jinftry, Your most trustworthy component supplier, welcome to send us the inquiry, thank you!
Do you have any questions about 74LVC30APW118 ?
Feel free to contact us:
