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Inverse Relation

Inverse Relation: An inverse relation is the opposite of a given relation obtained by interchanging or swapping the elements of each ordered pair. In simple terms, if (x, y) is a point in a relation R, then (y, x) is an element in the inverse relation.

In this article, we will learn about Inverse Relation including their domain, range, and other properties as well.



What is an Inverse Relation?

Inverse relation refer to pairs of elements from two sets where the roles of the elements are reversed in each pair. In other words, if there is a relation between two elements in one set, the inverse relation involves switching the positions of those elements to form a new pair.

For example, consider a relation that maps each person to their age: ={(John, 30), (Alice, 25), (Bob, 35)}.

The inverse relation would map each age to the corresponding person: R−1={(30, John), (25, Alice), (35, Bob)}.

Inverse Relation Meaning

Formally, if we have a relation R between elements of set A and set B, denoted as R: A B, then the inverse relation R−1 between elements of set B and set A is defined as follows:

R−1: B A

In simpler terms, if (a, b) is an ordered pair in the relation R, then (b, a) is an ordered pair in the inverse relation R−1.

Examples of Inverse Relation

Some of the examples of inverse relations are:

Properties of Inverse Relations

Some of the key properties of

Domain and Range of Inverse Relation

In an ordered pair, the first element represents the “domain,” while the second element represents the “range” of a relation. Let me illustrate this using an example:

Consider the sets A = {p, q, r, s, t} and B = {1, 2, 3, 4, 5}, with the relation R = {(p, 1), (q, 2), (r, 3), (s, 4), (t, 5)}.

Inverse Relation i.e., R⁻¹ = {(1,p), (2,q), (3,r), (4,s), (5,t)}.

Based on this, we can observe, the domain of R matches the range of R⁻¹. R⁻¹’s range is the same as its domain.

Inverse Relation Theorem

Statement: The inverse relation theorem claims that for each relation R, (R⁻¹)⁻¹ = R.

Proof: Let, (x,y) ∈ R.

If (x, y) belongs to relation R, then the inverse relation R-1 contains the pair (y, x).

As a result, (x, y) belongs to the inverse of the inverse relation (R-1)-1.

Since (x, y) belongs to (R-1)-1, and (R-1)-1 equals R, we can conclude that (x, y) ∈ R.

The theory states that for any relation R, (R-1)-1 = R.

Inverse Relation Graph

Inverse relations are represented graphically by drawing points and then reflecting them across the line y = x. Here are the steps:

Step 1: Select any point from the original graph.

Step 2: Swap the x and y values to create new coordinates that indicate the inverse connection.

Step 3: Draw these additional points on the graph to show the inverse relationship.

Example:

Simply reflect the original points across the line y = x to get the inverse relation graph.

Graphical Representation of Inverse Relation

Conclusion – Inverse Relation

In conclusion, inverse relation is the

In Conclusion, inverse relations are important in mathematics because they reveal reverse links between sets of elements. Their significance extends to a wide range of applications, including equation solving and function composition, cryptography, and data encryption. Understanding inverse relations helps to appreciate the symmetric nature of relationships and their reversal, which improves knowledge of mathematical concepts and real-world events. Inverse linkages continue to play an important role in unraveling complicated interactions and operations, helping problem solving and analysis in a wide range of industries.

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Inverse Relation Solved Examples

Example 1: Determine the inverse of the following relation. R = {(8, 9) (3, 5), (4, 6)}

Solution:

Given: R = {(8,9) (3,5), (4,6)}

The inverse of set R will be,

R⁻¹ = {(9,8), (5,3), (6,4)}

Example 2: Determine the inverse of the function R = (x, x2)where x is a prime number smaller than 15.

Solution:

The list of prime numbers less than 15 includes 2, 3, 5, 7, 11 and 13.

R = {(2,4), (3,9), (5,25), (7,49), (11, 121), (13, 169)}

The inverse of set R should be,

R⁻¹ = {(4,2), (9,3), (25,5), (49,7), (121, 11), (169, 13)}

Example 3: Determine the domain and the range of the relation R = (x, x2)where x is a even number smaller than 9.

Solution:

The list of even numbers less than 9 includes 2, 4, 6 and 8.

R = {(2,4), (4,16), (6,36), (8,64)}

  • Domain of R = {2, 4, 6, 8}
  • Range of R = {4, 16, 36, 64}

Inverse Relation: Practice Problems

Q1: Determine the domain and the range of the relation R = (x, x2), where x is a prime number smaller than 10.

Q2: Determine the inverse of the function R = (x, x3), where x is a odd number smaller than 20.

Q3: Determine the inverse of the following relation. R = {(15, 12), (18, 26), (24, 16)}

FAQs on Inverse Relation

What is Meaning of Inverse Relation?

The term “inverse relation” refers to a mathematical concept describing the relationship between two sets of elements where the roles of the elements are reversed in each pair.

How do you Identify Inverse Relationships?

We can identify inverse relationships by reversing the pairs of elements in a given relation. If (a, b) is in the original relation, then (b, a) is in the inverse relation.

What is the Inverse Relation Theorem?

The inverse relation theorem states that for every relation R, the inverse of (R⁻¹)⁻¹ is equal to R.

What is the Relationship of Graph of Relation and Inverse Relation?

The relationship between the graph of a relation and its inverse relation involves reflection across the line y = x. If a point (a, b) is on the graph of the original relation, then (b, a) will be on the graph of the inverse relation.

What is Inverse relation Graph?

An inverse relation graph illustrates the inverse relationship between two variables or sets of points. In the context of functions, if you have a function f(x) that maps elements from set A to set B, its inverse function, denoted as f-1(x), maps elements back from set B to set A.


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