Sets, in mathematics, are an organized collection of objects and can be represented in setbuilder form or roster form. Usually, sets are represented in curly braces {}, for example, A = {1,2,3,4} is a set. Also, check the set symbols here.
In sets theory, you will learn about sets and it’s properties. It was developed to describe the collection of objects. You have already learned about the classification of sets here. The set theory defines the different types of sets, symbols and operations performed.
Table of contents: 
Definition of Sets
Sets are represented as a collection of welldefined objects or elements and it does not change from person to person. A set is represented by a capital letter. The number of elements in the finite set is known as the cardinal number of a set.
What are the Elements of a Set
Let us take an example:
A = {1, 2, 3, 4, 5 }
Since a set is usually represented by the capital letter. Thus, A is the set and 1, 2, 3, 4, 5 are the elements of the set or members of the set. The elements that are written in the set can be in any order but cannot be repeated. All the set elements are represented in small letter in case of alphabets. Also, we can write it as 1 ∈ A, 2 ∈ A etc. The cardinal number of the set is 5. Some commonly used sets are as follows:
 N: Set of all natural numbers
 Z: Set of all integers
 Q: Set of all rational numbers
 R: Set of all real numbers
 Z^{+}: Set of all positive integers
Order of Sets
The order of a set defines the number of elements a set is having. It describes the size of a set. The order of set is also known as the cardinality.
The size of set whether it is is a finite set or an infinite set, said to be set of finite order or infinite order, respectively.
Also, check:
Representation of Sets
The sets are represented in curly braces, {}. For example, {2,3,4} or {a,b,c} or {Bat, Ball, Wickets}. The elements in the sets are depicted in either the Statement form, Roster Form or Set Builder Form.
Statement Form
In statement form, the welldefined descriptions of a member of a set are written and enclosed in the curly brackets.
For example, the set of even numbers less than 15.
In statement form, it can be written as {even numbers less than 15}.
Roster Form
In Roster form, all the elements of a set are listed.
For example, the set of natural numbers less than 5.
Natural Number = 1, 2, 3, 4, 5, 6, 7, 8,……….
Natural Number less than 5 = 1, 2, 3, 4
Therefore, the set is N = { 1, 2, 3, 4 }
Set Builder Form
The general form is, A = { x : property }
Example: Write the following sets in set builder form: A={2, 4, 6, 8}
Solution:
2 = 2 x 1
4 = 2 x 2
6 = 2 x 3
8 = 2 x 4
So, the set builder form is A = {x: x=2n, n ∈ N and 1 ≤ n ≤ 4}
Also, Venn Diagrams are the simple and best way for visualized representation of sets.
Types of Sets
We have several types of sets in Maths. They are empty set, finite and infinite sets, proper set, equal sets, etc. Let us go through the classification of sets here.
Empty Set
A set which does not contain any element is called an empty set or void set or null set. It is denoted by { } or Ø.
A set of apples in the basket of grapes is an example of an empty set because in a grapes basket there are no apples present.
Singleton Set
A set which contains a single element is called a singleton set.
Example: There is only one apple in a basket of grapes.
Finite set
A set which consists of a definite number of elements is called a finite set.
Example: A set of natural numbers up to 10.
A = {1,2,3,4,5,6,7,8,9,10}
Infinite set
A set which is not finite is called an infinite set.
Example: A set of all natural numbers.
A = {1,2,3,4,5,6,7,8,9……}
Equivalent set
If the number of elements is the same for two different sets, then they are called equivalent sets. The order of sets does not matter here. It is represented as:
n(A) = n(B)
where A and B are two different sets with the same number of elements.
Example: If A = {1,2,3,4} and B = {Red, Blue, Green, Black}
In set A, there are four elements and in set B also there are four elements. Therefore, set A and set B are equivalent.
Equal sets
The two sets A and B are said to be equal if they have exactly the same elements, the order of elements do not matter.
Example: A = {1,2,3,4} and B = {4,3,2,1}
A = B
Disjoint Sets
The two sets A and B are said to be disjoint if the set does not contain any common element.
Example: Set A = {1,2,3,4} and set B = {5,6,7,8} are disjoint sets, because there is no common element between them.
Subsets
A set ‘A’ is said to be a subset of B if every element of A is also an element of B, denoted as A ⊆ B. Even the null set is considered to be the subset of another set. In general, a subset is a part of another set.
Example: A = {1,2,3}
Then {1,2} ⊆ A.
Similarly, other subsets of set A are: {1},{2},{3},{1,2},{2,3},{1,3},{1,2,3},{}.
Note: The set is also a subset of itself.
If A is not a subset of B, then it is denoted as A⊄B.
Proper Subset
If A ⊆ B and A ≠ B, then A is called the proper subset of B and it can be written as A⊂B.
Example: If A = {2,5,7} is a subset of B = {2,5,7} then it is not a proper subset of B = {2,5,7}
But, A = {2,5} is a subset of B = {2,5,7} and is a proper subset also.
Superset
Set A is said to be the superset of B if all the elements of set B are the elements of set A. It is represented as A ⊃ B.
For example, if set A = {1, 2, 3, 4} and set B = {1, 3, 4}, then set A is the superset of B.
Universal Set
A set which contains all the sets relevant to a certain condition is called the universal set. It is the set of all possible values.
Example: If A = {1,2,3} and B {2,3,4,5}, then universal set here will be:
U = {1,2,3,4,5}
Operations on Sets
In set theory, the operations of the sets are carried when two or more sets combine to form a single set under some of the given conditions. The basic operations on sets are:
 Union of sets
 Intersection of sets
 A complement of a set
 Cartesian product of sets.
 Set difference
Basically, we work more on union and intersection of sets operations, using Venn diagrams.
Union of Sets
If set A and set B are two sets, then A union B is the set that contains all the elements of set A and set B. It is denoted as A ∪ B.
Example: Set A = {1,2,3} and B = {4,5,6}, then A union B is:
Intersection of Sets
If set A and set B are two sets, then A intersection B is the set that contains only the common elements between set A and set B. It is denoted as A ∩ B.
Example: Set A = {1,2,3} and B = {4,5,6}, then A intersection B is:
A ∩ B = { } or Ø
Since A and B do not have any elements in common, so their intersection will give null set.
Complement of Sets
The complement of any set, say P, is the set of all elements in the universal set that are not in set P. It is denoted by P’.
Properties of Complement sets
 P ∪ P′ = U
 P ∩ P′ = Φ
 Law of double complement : (P′ )′ = P
 Laws of empty/null set(Φ) and universal set(U), Φ′ = U and U′ = Φ.
Cartesian Product of sets
If set A and set B are two sets then the cartesian product of set A and set B is a set of all ordered pairs (a,b), such that a is an element of A and b is an element of B. It is denoted by A × B.
We can represent it in setbuilder form, such as:
A × B = {(a, b) : a ∈ A and b ∈ B}
Example: set A = {1,2,3} and set B = {Bat, Ball}, then;
A × B = {(1,Bat),(1,Ball),(2,Bat),(2,Ball),(3,Bat),(3,Ball)}
Difference of Sets
If set A and set B are two sets, then set A difference set B is a set which has elements of A but no elements of B. It is denoted as A – B.
Example: A = {1,2,3} and B = {2,3,4}
A – B = {1}
Sets Formulas
Some of the most important set formulas are:
For any three sets A, B and C 
n ( A ∪ B ) = n(A) + n(B) – n ( A ∩ B) 
If A ∩ B = ∅, then n ( A ∪ B ) = n(A) + n(B) 
n( A – B) + n( A ∩ B ) = n(A) 
n( B – A) + n( A ∩ B ) = n(B) 
n( A – B) + n ( A ∩ B) + n( B – A) = n ( A ∪ B ) 
n ( A ∪ B ∪ C ) = n(A) + n(B) + n(C) – n ( A ∩ B) – n ( B ∩ C) – n ( C ∩ A) + n ( A ∩ B ∩ C) 
Also, check the set symbols here.
Download Free PDFs for Daily Practice Problems and Worksheet for Sets
Daily Practice Problems – SET 1 
Worksheet – SET 1 
Video Lesson
Applied Concept – Cardinality of Sets
Properties of Sets
Commutative Property :

Associative Property :

Distributive Property :

De morgan’s Law :

Complement Law :

Idempotent Law And Law of a null and universal set :
For any finite set A

⇒ Learn more about De Morgan’s First Law here.
Example of Sets
Here are a few examples, given to represent the elements of a set.
Example 1:
Write the given statement in three methods of representation of a set:
The set of all integers that lies between 1 and 5
Solution:
The methods of representations of sets are:
Statement Form: { I is the set of integers that lies between 1 and 5}
Roster Form: I = { 0,1, 2, 3,4 }
Setbuilder Form: I = { x: x ∈ I, 1 < x < 5 }
Example 2:
Find A U B and A ⋂ B and A – B.
If A = {a, b, c, d} and B = {c, d}.
Solution:
A = {a, b, c, d} and B = {c, d}
A U B = {a, b, c, d}
A ⋂ B = {c, d} and
A – B = {a, b}
For more maths concepts, keep visiting BYJU’S and get various maths related videos to understand the concept in an easy and engaging way.
Frequently Asked Questions on Sets
What is set? Give an example.
A set is a collection of elements or numbers or objects, represented within the curly brackets { }.
For example: {1,2,3,4} is a set of numbers.
What are the different forms of sets?
There are three forms in which we can represent the sets. They are:
Statement form: A set of even number less than 20
Roster form: A = {2,4,6,8,10,12,14,16,18}
Set builder form: A = {x: x=2n, n ∈ N and 1 ≤ n ≤ 20}
What are the types of sets?
The sets are of different types, such as empty set, finite and infinite set, equal set, equivalent set, proper set, disjoint set, subsets, singleton set.
Check: Types of Sets
Why do we use sets in Maths?
The purpose of using sets is to represent the collection of relevant objects in a group. In maths, we usually represent a group of numbers like a group of natural numbers, collection of rational numbers, etc.
What are the elements of sets?
The elements of sets are the numbers, objects, symbols, etc contained in a set. For example, in A={12,33.56,}; 12, 33 and 56 are the elements of sets.
very nice explanation
I appreciate the way of note presentation .
This made me understand set theories real quick for my exam tomorrow. Very detailed and easy explanation. Keep up the good work. I always use your sites for my maths problem
Am got so much help from this website
So am thankful for these