What does NAND gate mean

AND gates followed by an inverter

Inversion followed by AND gates

Basic Logic Gates - Types, Functions, Truth Table, Boolean Expressions

Logic gates are an important concept if you are studying electronics. These are important digital devices that are mainly based on the Boolean function. Logic gates are used to carry out logical operations on single or multiple binary inputs and give one binary output. In simple terms, logic gates are the electronic circuits in a digital system.

In this lesson, we will further look at the different types of basic logic gates with their truth table and understand what each one is designed for.

Types of Basic Logic Gates

There are several basic logic gates used in performing operations in digital systems. The common ones are;

OR Gate
AND Gate
NOT Gate
XOR Gate

Additionally, these gates can also be found in a combination of one or two. Therefore we get other gates such as NAND Gate, NOR Gate, EXOR Gate, EXNOR Gate.

Also Read: Transistor

OR Gate

In OR gate the output of an OR gate attains the state 1 if one or more inputs attain the state 1.

Logic symbol of OR gate

The Boolean expression of OR gate is Y = A + B, read as Y equals A ‘OR’ B.

The truth table of a two-input OR basic gate is given as;

A	B	Y
0	0	0
0	1	1
1	0	1
1	1	1

AND Gate

In AND gate the output of an AND gate attains the state 1 if and only if all the inputs are in state 1.

Logic Symbol of AND Gate

The Boolean expression of AND gate is Y = A.B

The truth table of a two-input AND basic gate is given as;

A	B	Y
0	0	0
0	1	0
1	0	0
1	1	1

NOT Gate

In NOT gate the output of a NOT gate attains the state 1 if and only if the input does not attain the state 1.

Logic Symbol of NOT gate

The Boolean expression is Y =

\(\begin{array}{l}\bar{A}\end{array} \)

, read as Y equals NOT A.

The truth table of NOT gate is as follows;

A	Y
0	1
1	0

The three gates (OR, AND and NOT), when connected in various combinations, give us basic logic gates such as NAND, NOR gates, which are the universal building blocks of digital circuits.

NAND Gate

This basic logic gate is the combination of AND and NOT gate.

Logic Symbol of NAND gate

The Boolean expression of NAND gate is Y =

\(\begin{array}{l}\bar{A.B}\end{array} \)

The truth table of a NAND gate is given as;

A	B	Y
0	0	1
0	1	1
1	0	1
1	1	0

NOR Gate

This gate is the combination of OR and NOT gate.

Logic Symbol of NOR

The Boolean expression of NOR gate is Y =

\(\begin{array}{l}\bar{A+B}\end{array} \)

The truth table of a NOR gate is as follows;

A	B	Y
0	0	1
0	1	0
1	0	0
1	1	0

Exclusive-OR gate (XOR Gate)

In XOR gate the output of a two-input XOR gate attains the state 1 if one adds only input attains the state 1.

Logic Symbol of XOR gate

The Boolean expression of the XOR gate is

\(\begin{array}{l}A.\bar{B}+\bar{A}.B\end{array} \)

\(\begin{array}{l}Y = A \bigoplus B\end{array} \)

The truth table of an XOR gate is;

A	B	Y
0	0	0
0	1	1
1	0	1
1	1	0

Exclusive-NOR Gate (XNOR Gate)

In XNOR gate the output is in state 1 when its both inputs are the same that is, both 0 or both 1.

Logic Symbol of XNOR gate

The Boolean expression of XNOR gate

The truth table of an XNOR gate is given below;

A	B	Y
0	0	1
0	1	0
1	0	0
1	1	1

Application Of Logic Gates

Logic gates have a lot of applications but they are mainly based upon their mode of operations or their truth table. Basic logic gates are often found in circuits such as safety thermostat, push-button lock, automatic watering system, light-activated burglar alarm and many other electronic devices.

One of the primary benefits is that basic logic gates can be used in a mixture of different combinations if the operations are advanced. Besides, there is no limit to the number of gates that can be used in a single device. However, it can be restricted due to the given physical space in the device. In digital integrated circuits (ICs) we will find an array of the logic gate area unit.

De Morgan’s Theorem

First theorem – It states that the NAND gate is equivalent to a bubbled OR gate.

\(\begin{array}{l}\bar{A.B} = \bar{A}+ \bar{B}\end{array} \)

Second theorem – It states that the NOR gate is equivalent to a bubbled AND gate.

\(\begin{array}{l}\overline{A+B} = \bar{A}. \bar{B}\end{array} \)

Important Conversions

1) The ‘NAND’ gate: From ‘AND’ and ‘NOT’ gate.

From 'AND' and 'NOT' gate

Boolean expression and truth table :

Y=A⋅B¯¯¯¯¯¯¯¯¯¯¯

A	B	Y′=A⋅B	Y
0	0	0	1
0	1	0	1
1	0	0	1
1	1	1	0

(2) The ‘NOR’ gate: From ‘OR’ and ‘NOT’ gate

From 'OR' and 'NOT' gate

Boolean expression and truth table :

Y=A+B

A	B	Y′=A+B	Y
0	0	0	1
0	1	1	0
1	0	1	0
1	1	1	0

(3) The ‘XOR’ gate: From ‘NOT’, ‘AND’ and ‘OR’ gate.

The logic gate which gives high output (i.e., 1) if either input A or input B but not both are high (i.e. 1) is called exclusive OR gate or the XOR gate. It may be noted that if both the inputs of the XOR gate are high, then the output is low (i.e., 0).

XOR Gate image 1 JEE

XOR gate image 2 JEE

Boolean expression and truth table:

\(\begin{array}{l}A.\bar{B}+\bar{A}.B\end{array} \)

\(\begin{array}{l}Y = A \bigoplus B\end{array} \)

A	B	Y
0	0	0
0	1	1
1	0	1
1	1	0

(4) The Exclusive nor (XNOR) gate XOR + NOT

Exclusive Nor (XNOR) Gate

Boolean expression:

\(\begin{array}{l}Y= \bar{(A\bigoplus B)}\end{array} \)

A	B	Output
0	0	1
0	1	0
1	0	0
1	1	1