Real Numbers Class-10th Board

Real Numbers Class-10th Board: The concept of real numbers is an integral part of mathematics that students must master to build a strong foundation for higher studies. Real numbers encompass various types of numbers such as natural numbers, whole numbers, integers, rational, and irrational numbers, all of which form the real number system. In this post, we will cover the fundamental concepts, properties, theorems, and examples related to real numbers as per the Class 10 curriculum.

This is the pyqs detailed solution.

Natural numbers are the set of positive integers that start from 1 and go on infinitely. They are often referred to as “counting numbers. Generally, It is represented by N.

Set Representation:

N = {1, 2, 3, 4, 5, 6, 7, 8, …}

Properties:

  • The smallest natural number is 1.
  • They are infinite and continue endlessly.
  • Natural numbers do not include zero (0), negative numbers, fractions, or decimals.

Whole numbers are the set of all non-negative integers. This set includes all natural numbers along with zero.

Generally, It is represented by W.

Set Representation:

W = {0, 1, 2, 3, 4, 5, 6, 7, 8, …}

Properties:

  • The smallest whole number is 0.
  • Whole numbers do not include negative numbers, fractions, or decimals.
  • Like natural numbers, the set of whole numbers is infinite and continues endlessly.

Integers are the set of all whole numbers and their negatives. This includes positive numbers, zero, and negative numbers without fractions or decimals. Generally, It is denoted by Z.

Set Representation:

Z = {…, -2, -1, 0, 1, 2, …}

Properties:

  • Integers include both positive and negative numbers, along with zero.
  • They do not include fractions or decimals.
  • The set of integers is infinite in both directions (positive and negative).

A rational numbers is any numbers that can be represented in the form of p/q format. where, p and q are integers and q should not be equal to zero. It is generally denoted by Q.

Rational numbers include both positive and negative fractions, whole numbers, and integers, as they can all be expressed as fractions.

Set Representation:

Q = { p/q | p,q ∈ Z and q ≠ 0 }

A irrational numbers is any numbers that can not be represented in the form of p/q format. where, p and q are integers and q should not be equal to zero. It is generally denoted by I.

Their decimal expansions are non-terminating and non-repeating.

Statement: For any two positive integers a and b, there exist unique integers q and r such that:

a = bq + r, 0 ≤ r < b

Here, is the dividend, b is the divisor, q is the quotient, and r is the remainder.

Application:

Euclid’s division lemma is used to find the Highest Common Factor (HCF) of two numbers.

Example:

Find the HCF of 455 and 42 using Euclid’s division lemma.

  1. Divide 455 by 42 => 455 = 42 * 10 + 35
  2. Divide 42 by 35 => 42 = 35 * 1 + 7
  3. Divide 35 by 7 => 35 = 7 * 5 + 0

Hence, the remainder is 0, and the HCF is 7.

Statement: Every composite number can be expressed (or factorized) as a product of primes, and this factorization is unique, except for the order of the prime factors.

Application:

This theorem is used for finding the LCM and HCF of two numbers using their prime factorization.

Example:

Factorize 140.

140 = 22 * 5 * 7

Relation between HCF and LCM:

HCF * LCM = Product of the two numbers

Example:

Step-01: Prime Factorization:

12 = 22 * 3, 18 = 2 * 32

Step-02: HCF = Product of smallest powers of common prime factors:

HCF = 21 * 31 = 6

Step-03: LCM = Prodcut of highest powers of all prime factors:

LCM = 22 * 32 = 36

Verification: HCF * LCM = 6 * 36 = 216 and 12 * 18 = 216

Terminating Decimal: A rational number has a terminating decimal expansion if the denominator (in its lowest form) has only powers of 2 or 5.

Non-Terminating, Repeating Decimal: A rational number has a non-terminating, repeating decimal expansion if the denominator (in its lowest form) has prime factors other than 2 or 5.

Irrational Numbers: Have non-terminating, non-repeating decimal expansions.

Example:

1/8 = 0.125 (terminating decimal).

1/3 = 0.3333… (non-terminating repeating)

π = 3.1415926535. . . (non-terminating, non-repeating)

Rational Numbers: Can be expressed in the form p/q, where p and q are integers, and q not equal to 0.

Irrational Numbers: Cannot be expressed as p/q, and their decimal expansion does not terminte or repeat.

  • Euclid’s Division Lemma: a = bq + r
  • HCF * LCM = Product of two numbers

Solution:

Step-01: Assume root(5) is a rational number.

So, root(5) = p/q, where p and q are co-prime integers, and q not equal to 0.

step-02: Squaring both sides:

5 = p2 / q2

p2 = 5q2

This means p2 is divisble by 5, so p must be divisible by 5. Let p = 5k for some interger k.

step-03: Substituting p = 5k into the equation:

(5k)2 = 5q2

25 k2 = 5q2

q2 = 5k2

This implies q2 is divisible by 5, so q is also divisible by 5.

step-04: Since both p and q are divisible by 5, they have a common factor of 5, which contradicts the assumption that p and q are co-prime.

Hence, root(5) is irrational.

Solution: Using Euclid’s division algorithm:

step-01: Divide 72 by 56:

72 = 56 * 1 + 16

Here, the remainder is 16

step-02: Now, divide 56 by 16:

56 = 16 * 3 + 8

The remainder is 8

step-03: Next, divide 16 by 8:

16 = 8 * 2 + 0

The remainder is 0, so the division process stops here.

Hence, the HCF of 56 and 72 is 8.

Solution:

Step-01: Prime factorization of 120:

120 = 23 * 3 * 5

step-02: Prime factorization of 144:

144 = 24 * 32

step-03: Finding the HCF:

The HCF is the product of the smallest powers of all common prime factors.

HCF = 23 * 3 = 24

step-04: Finding the LCM:

The LCM is the product of the highest power of all prime factors.

LCM = 24 * 32 * 5 = 720

Thus, the HCF of 120 and 144 is 24, and the LCM of 120 and 144 is 720.

Solution:

A rational number has a terminating decimal expansion if its denominator (in its lowest form) has only the prime factors 2 and/or 5.

step-01: The given number is 13/25.

step-02: The prime factorization of the denomenator 25 is:

25 = 52

since the denomenator contains only the prime factor 5, the decimal expansion of 13/25 will be terminating.

thus, 13/25 = 0.52 is a terminating decimal.

Solution:

A rational number has a non-terminating repeating decimal expansion if its denominator (in its lowest form) has prime factors other than 2 or 5.

step-01: The given number is 7/22.

step-02: The prime factorization of 22 is:

22 = 2 * 11

since the denomintor has a prime factor 11 (which is not 2 or 5), the decimal expansion of 7/22 will be non-terminating and repeating.

step-03: Dividing 7 by 22:

7/22 = 0.318181831818183181818. . .

the repeating block is 3181818.

Thus, 7/22 has a non-terminating repeating decimal expansion.

What are Real Numbers?

Real numbers include both rational and irrational numbers. Any number that can be found on the number line is a real number. Examples include:
Rational Numbers: 1/2, 3, 2/7 etc.
Irrational Numbers: root(2), root(5), Pi, etc.

What is Euclid’s Division Lemma?

Statement: For any two positive integers a and b, there exist unique integers q and r such that:
a = bq + r, 0 ≤ r < b
Here, is the dividend, b is the divisor, q is the quotient, and r is the remainder.
Application:
Euclid’s division lemma is used to find the Highest Common Factor (HCF) of two numbers.

What is the Fundamental Theorem of Arithmetic?

The Fundamental Theorem of Arithmetic states that every composite number can be expressed as a product of primes, and this factorization is unique, except for the order of the factors. For example:
140 = 22 * 5 * 7

How is the HCF and LCM of two numbers related?

The HCF and LCM of two numbers are related by the following formula:
𝐻𝐶𝐹 × 𝐿𝐶𝑀 = Product of the two numbers
HCF×LCM=Product of the two numbers
This relation is very helpful when calculating the LCM and HCF of large numbers.

What is the difference between terminating and non-terminating decimal expansions?

Terminating Decimal Expansion: A decimal that ends after a finite number of digits. For example,
0.25
0.25 is a terminating decimal.
Non-Terminating Decimal Expansion: A decimal that continues without ending. Non-terminating decimals can either repeat or not repeat:
Repeating Decimal: For example, 0.33333. . .
Non-Repeating Decimal: For example, Pi = 3.14159. . .

How do you prove that a number like root(2), root(3) or root(5) is irrational?

Solution:
Step-01: Assume root(5) is a rational number.
So, root(5) = p/q, where p and q are co-prime integers, and q not equal to 0.
step-02: Squaring both sides:
5 = p2 / q2
p2 = 5q2
This means p2 is divisble by 5, so p must be divisible by 5. Let p = 5k for some interger k.
step-03: Substituting p = 5k into the equation:
(5k)2 = 5q2
25 k2 = 5q2
q2 = 5k2
This implies q2 is divisible by 5, so q is also divisible by 5.
step-04: Since both p and q are divisible by 5, they have a common factor of 5, which contradicts the assumption that p and q are co-prime.
Hence, root(5) is irrational.

What kind of decimal expansion do rational numbers have?

Rational numbers have either a terminating or a non-terminating repeating decimal expansion. The type of decimal expansion depends on the prime factors of the denominator when the rational number is expressed in its lowest terms:
If the denominator has only 2 and/or 5 as prime factors, the decimal expansion will be terminating.
If the denominator has prime factors other than 2 or 5, the decimal expansion will be non-terminating repeating.

What are Irrational Numbers?

A irrational numbers is any numbers that can not be represented in the form of p/q format. where, p and q are integers and q should not be equal to zero. It is generally denoted by I.
Their decimal expansions are non-terminating and non-repeating.

How do you find the HCF of two numbers using Euclid’s Division Algorithm?

To find the HCF of two numbers using Euclid’s Division Algorithm:
Divide the larger number by the smaller number and find the remainder.
Replace the larger number with the smaller number and the smaller number with the remainder.
Repeat the process until the remainder is 0. The divisor at this step is the HCF of the two numbers.

How do you check if a given rational number has a terminating decimal expansion?

To check if a given rational number p/q has a terminating decimal expansion:
Simplify the rational number to its lowest terms.
Check the prime factorization of the denominator.
If the denominator has only powers of 2 or 5, the decimal expansion will be terminating.
If the denominator has prime factors other than 2 or 5, the decimal expansion will be non-terminating repeating.

What is the significance of the Fundamental Theorem of Arithmetic?

The Fundamental Theorem of Arithmetic ensures that every composite number has a unique prime factorization. This uniqueness is crucial in various areas of mathematics, including finding the HCF and LCM, and solving number theory problems.
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