SETS AND RELATIONS HAHAHAHAHAHAHAHAH.ppt

SYLLABUS
Set Operations
Representations and Properties of Relations
Equivalence Relations
Partially Ordering

SET OPERATIONS
Set operations is a concept similar to fundamental operations on numbers.
Sets in math deal with a finite collection of objects, be it numbers, alphabets, or any
real-world objects.
Sometimes a necessity arises wherein we need to establish the relationship between
two or more sets.
There comes the concept of set operations.
There are four main set operations which include set union, set intersection, set
complement, and set difference.

THERE ARE FOUR MAIN KINDS OF SET
OPERATIONS WHICH ARE:
Union of sets
Intersection of sets
Complement of a set
Difference between sets/Relative Complement

UNION OF SETS
For two given sets A and B,
A B (read as A union B) is the set of distinct elements that belong to set A and B or
∪
both.
The number of elements in A B is given by
∪
n(A B) = n(A) + n(B) n(A B),
∪ − ∩
where n(X) is the number of elements in set X.
To understand this set operation of the union of sets better, let us consider an example:
If A = {1, 2, 3, 4} and B = {4, 5, 6, 7}, then the union of A and B is given by A B =
∪
{1, 2, 3, 4, 5, 6, 7}.

INTERSECTION OF SETS
For two given sets A and B, A B (read as A intersection B) is the set of common
∩
elements that belong to set A and B.
The number of elements in A B is given by
∩
n(A B) = n(A)+n(B) n(A B),
∩ − ∪
where n(X) is the number of elements in set X.
To understand this set operation of the intersection of sets better, let us consider an
example:
If A = {1, 2, 3, 4} and B = {3, 4, 5, 7}, then the intersection of A and B is given by A
B = {3, 4}.
∩

SET DIFFERENCE
The set operation difference between sets implies subtracting the elements from a set
which is similar to the concept of the difference between numbers.
The difference between sets A and B denoted as A B lists all the elements that are
−
in set A but not in set B.
To understand this set operation of set difference better, let us consider an example:
If
A = {1, 2, 3, 4} and B = {3, 4, 5, 7}, then the difference between sets A and B is
given by A - B = {1, 2}.

COMPLEMENT OF SETS
The complement of a set A denoted as A or A
′ c
(read as A complement) is defined as
the set of all the elements in the given universal set(U) that are not present in set A.
To understand this set operation of complement of sets better, let us consider an
example:
If U = {1, 2, 3, 4, 5, 6, 7, 8, 9} and A = {1, 2, 3, 4}, then the complement of set A is
given by A' = {5, 6, 7, 8, 9}.

SETS AND RELATIONS HAHAHAHAHAHAHAHAH.ppt

TYPES OF RELATIONS
There are 8 main types of relations which include:
Empty Relation
Universal Relation
Identity Relation
Inverse Relation
Reflexive Relation
Symmetric Relation
Transitive Relation
Equivalence Relation

TYPES OF RELATIONS(CONT….)
Empty Relation
An empty relation (or void relation) is one in which there is no relation between any elements of a
set. For example, if set A = {1, 2, 3} then, one of the void relations can be R = {x, y} where, |x –
y| = 8. For empty relation,
R = A × A
φ ⊂
Universal Relation
A universal (or full relation) is a type of relation in which every element of a set is related to each
other. Consider set A = {a, b, c}. Now one of the universal relations will be R = {x, y} where, |x –
y| ≥ 0. For universal relation,
R = A × A

Identity Relation
In an identity relation, every element of a set is related to itself only. For example, in a
set A = {a, b, c}, the identity relation will be I = {a, a}, {b, b}, {c, c}. For identity relation,
I = {(a, a), a A}
∈
Inverse Relation
Inverse relation is seen when a set has elements which are inverse pairs of another set.
For example if set A = {(a, b), (c, d)}, then inverse relation will be R-1
= {(b, a), (d, c)}.
So, for an inverse relation,
R-1
= {(b, a): (a, b) R}
∈

Reflexive Relation
In a reflexive relation, every element maps to itself. For example, consider a set A = {1, 2,}. Now an
example of reflexive relation will be R = {(1, 1), (2, 2), (1, 2), (2, 1)}. The reflexive relation is given by-
(a, a) R
∈
Symmetric Relation
In a symmetric relation, if a=b is true then b=a is also true. In other words, a relation R is symmetric
only if (b, a) R is true when (a,b) R. An example of symmetric relation will be R = {(1, 2), (2, 1)}
∈ ∈
for a set A = {1, 2}. So, for a symmetric relation,
aRb bRa, a, b A
⇒ ∀ ∈
.

Transitive Relation
For transitive relation, if (x, y) R, (y, z) R, then (x, z) R. For a transitive
∈ ∈ ∈
relation,
aRb and bRc aRc a, b, c A
⇒ ∀ ∈
Equivalence Relation
If a relation is reflexive, symmetric and transitive at the same time it is known as an
equivalence relation

PARTIALLY ORDERING
Partial Order Relations
A relation R on a set A is called a partial order relation if it satisfies the following
three properties:
Relation R is Reflexive, i.e. aRa a A.
∀ ∈
Relation R is Antisymmetric, i.e., aRb and bRa a = b.
⟹
Relation R is transitive, i.e., aRb and bRc aRc.
⟹

SETS AND RELATIONS HAHAHAHAHAHAHAHAH.ppt

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