Logic gates and inverters are a group of logic gates and inverters that performs simple logical operations AND, NOT, OR, and others on particular logic signals.. Unlike flip-flops, they don't have the ability to store information, and they react instantly to signals sent to their inputs. Despite being long since replaced by integrated circuit solutions for the realization of complex functions, discrete gates are still usable in situations requiring only the most basic logical operations. The Logic NOT gate is often called an inverter.
Why Are Logic Gates and Inverters Important?
The logic gates and inverters are typically described as the primary building blocks of an electronic circuit. Getting to know the association between the different logic gates enables electronic professionals to produce an extremely complicated system that facilitates advanced technologies. Physical parts of a circuit called logic gates implement a Boolean function to control the flow of a signal by converting it to binary information.
What are the Different Types of Logic Gates and Inverters?
The type of binary input that logic gates receive can affect how they operate in several ways. The typical logic gate types found in most electronic circuits are outlined below:
- NOT logic Gate
- AND Logic Gate
- OR Logic Gate
- NOR Logic Gate
- XOR Logic Gate
- XNOR Logic Gate
- NAND Logic Gate
Common Application of Logic Gates and Inverters:
Logic gates and inverters are typically used in the following areas:
- Multiplexers & Demultiplexers
- Half and full adders
- Encoders & Decoders
Additionally, AND gate, NOT gate, and OR gate have uses in many other fields, such as:
AND Gate - This type of gate tends to patrol screening for data flowing through an electronic channel.
NOT Gate - NOT gates are also called inverters as they utilize an output completely opposite to the input they obtain.
OR Gate - Various industrial plants use OR logic gates to carry out their procedures accurately. Temperature and pressure sensors feed information into OR gates, which then produce an output that corrects the errors.
