| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Nexperia |
IC GATE AND 4CH 2-INP 14TSSOP |
603 |
|
 |
Nexperia |
IC GATE NAND 4CH 2-INP 14DHVQFN |
9156 |
|
 |
Nexperia |
IC GATE OR 4CH 2-INP 14SO |
15540 |
|
 |
Nexperia |
IC GATE NAND 2CH 2IN 8XSON |
4565 |
|
 |
Nexperia |
IC GATE OR 1CH 2-INP 5TSSOP |
1113 |
|
 |
Nexperia |
IC INVERT SCHMITT 1CH 1IN 5TSSOP |
4782 |
|
 |
Nexperia |
IC GATE NAND 4CH 2-INP 14TSSOP |
1430 |
|
 |
Nexperia |
IC GATE NAND 4CH 2-INP 14SO |
0 |
|
 |
Nexperia |
IC GATE XOR 4CH 2-INP 14SSOP |
165 |
|
 |
Nexperia |
IC GATE AND 3CH 3-INP 14TSSOP |
0 |
|
 |
Nexperia |
FUNC, 2 INPUT, CMOS, PDSO8 |
0 |
|
 |
Nexperia |
IC INVERT SCHMITT 3CH 3IN 8VSSOP |
0 |
|
 |
Nexperia |
IC GATE AND 1CH 3-INP 6XSON |
4553 |
|
 |
Nexperia |
IC INVERTER 2CH 2-INP 6XSON |
189132 |
|
 |
Nexperia |
IC INVERT SCHMITT 6CH 6-INP 14SO |
5425 |
|
 |
Nexperia |
IC GATE OR 1CH 2-INP 5TSSOP |
3447 |
|
 |
Nexperia |
IC INVERTER 6CH 6-INP 14DHVQFN |
0 |
|
 |
Nexperia |
IC INVERTER 1CH 1-INP 5TSSOP |
0 |
|
 |
Nexperia |
IC INVERTER 1CH 1-INP 6XSON |
0 |
|
 |
Nexperia |
IC GATE NAND 4CH 2-INP 14SO |
0 |
|
Logic gates and inverters are fundamental components of digital integrated circuits (ICs). They perform basic logical operations (AND, OR, NOT, etc.) and signal inversion, forming the building blocks of complex digital systems. These components enable Boolean algebra implementation in hardware, driving functions in computers, communication systems, industrial automation, and consumer electronics. Their reliability, speed, and miniaturization have been critical to advancements in modern electronics.
| Type | Functional Characteristics | Application Examples |
|---|---|---|
| AND Gate | Outputs HIGH only when all inputs are HIGH | Address decoding in memory circuits |
| OR Gate | Outputs HIGH if at least one input is HIGH | Signal combining in control systems |
| NOT Gate (Inverter) | Reverses input signal (HIGH LOW) | Digital signal conditioning |
| NAND Gate | AND followed by inversion (universal gate) | Universal logic implementation |
| NOR Gate | OR followed by inversion (universal gate) | High-speed arithmetic circuits |
| XOR Gate | Outputs HIGH when inputs differ | Error detection/correction circuits |
Logic gates and inverters are fabricated using semiconductor technologies like CMOS (Complementary Metal-Oxide-Semiconductor), TTL (Transistor-Transistor Logic), or ECL (Emitter-Coupled Logic). A typical CMOS-based gate includes:
Advanced nodes (e.g., 7nm FinFET) integrate 3D transistor structures for improved performance.
| Parameter | Description | Importance |
|---|---|---|
| Propagation Delay | Time between input change and output response | Determines maximum operating frequency |
| Supply Voltage (VCC) | Operating voltage range (e.g., 1.8V 5.5V) | Defines compatibility with system voltage |
| Power Dissipation | Energy consumed during operation | Impacts thermal management and battery life |
| Output Drive Capability | Maximum current/voltage output | Dictates fan-out and load capacity |
| Operating Temperature | Temperature range (-40 C to 125 C) | Ensures reliability in harsh environments |
| Manufacturer | Representative Products | Key Features |
|---|---|---|
| Texas Instruments | SN74LVC1G08 (AND gate) | Ultra-low power, 1.65V 5.5V supply |
| NXP Semiconductors | 74HCT03 (NAND gate) | High-speed CMOS, TTL-compatible |
| STMicroelectronics | STM74HC04 (Hex Inverter) | Industrial temperature range |
| Intel | FPGA-based logic arrays | Reconfigurable gate-level logic |
Key considerations include:
Example: Choosing SN74LVC1G32 (OR gate) for a 3.3V IoT device ensures low power consumption and compact integration.