Class 10 Chapter 1 (Real Numbers)

 

Real numbers for class 10 notes are given here in detail. Go through the below article to learn the real number concept in an easy way.

Introduction to Real Numbers

Real Numbers

• Real numbers constitute the union of all rational and irrational numbers.
• Any real number can be plotted on the number line.

Euclid’s Division Lemma

• Euclid’s Division Lemma states that given two integers a and b, there exists a unique pair of integers q and r such that $a=b\times q+rand0\le r<b$.
• This lemma is essentially equivalent to : dividend = divisor $\times$ quotient + remainder
• In other words, for a given pair of dividend and divisor, the quotient and remainder obtained are going to be unique.
  

Euclid’s Division Algorithm

• Euclid’s Division Algorithm is a method used to find the H.C.F of two numbers, say a and b where a > b.
• We apply Euclid’s Division Lemma to find two integers q and r such that $a=b\times q+rand0\le r<b$.
• If r = 0, the H.C.F is b, else, we apply Euclid’s division Lemma to b (the divisor) and r (the remainder) to get another pair of quotient and remainder.
• The above method is repeated until a remainder of zero is obtained. The divisor in that step is the H.C.F of the given set of numbers.

 

The Fundamental Theorem of Arithmetic

Prime Factorization

• Prime Factorization is the method of expressing a natural number as a product of prime numbers.
• Example: $36=2\times 2\times 3\times 3$  is the prime factorization of 36.

Fundamental Theorem of Arithmetic

• The Fundamental Theorem of Arithmetic states that the prime factorization for a given number is unique if the arrangement of the prime factors is ignored.
• Example: $36=2\times 2\times 3\times 3$ OR, $36=2\times 3\times 2\times 3$
• Therefore, 36 is represented as a product of prime factors (Two 2s and two 3s) ignoring the arrangement of the factors.

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Method of Finding LCM

Example: To find the Least Common Multiple  (L.C.M) of 36 and 56,

1.  $36=2\times 2\times 3\times 3$
    $56=2\times 2\times 2\times 7$
2.  The common prime factors are $2\times 2$
3.  The uncommon prime factors are  $3\times 3$ for 36 and $2\times 7$ for 56.
4. LCM of 36 and 56 = $2\times 2\times 3\times 3\times 2\times 7$  which is 504

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Method of Finding HCF

H.C.F can be found using two methods – Prime factorisation and Euclid’s division algorithm.

• Prime Factorisation:
  • Given two numbers, we express both of them as products of their respective prime factors. Then, we select the prime factors that are common to both the numbers
  • Example – To find the H.C.F of 20 and 24
    $20=2\times 2\times \mathrm{5 \; and}$$24=2\times 2\times 2\times 3$
  • The factor common to 20 and 24 is $2\times 2,$ which is 4, which in turn is the H.C.F of 20 and 24.
• Euclid’s Division Algorithm:
• Example: To find the HCF of 18 and 30
  

  Finding the HCF of 18 and 30

  
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• 
  
• It is the repeated use of Euclid’s division lemma to find the H.C.F of two numbers.
• The required HCF is 6.
  

Product of Two Numbers = HCF X LCM of the Two Numbers

• For any two positive integers a and b,
  $a\times b=H.C.F\times L.C.M.$
• Example – For 36 and 56, the H.C.F is 4 and the L.C.M is 504
  $36\times 56=2016$
  $4\times 504=2016$
  Thus, $36\times 56=4\times 504$
• The above relationship, however, doesn’t hold true for 3 or more numbers

To know Relationship between LCM and HCF, visit here.

Applications of HCF & LCM in Real-World Problems

L.C.M can be used to find the points of common occurrence. For example,ringing of bells that ring    with different frequencies, the time at which two persons running at different speeds meet, and so on.

Revisiting Irrational Numbers

Irrational Numbers

Any number that cannot be expressed in the form of p/q (where p and q are integers and $q\ne 0$.) is an  irrational number. Examples √2$,\pi ,$ e and so on.

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Number theory: Interesting results

• If a number p (a prime number) divides $a^2$, then p divides a. Example: 3 divides $6^2$ i.e 36, which implies that 3 divides 6.
• The sum or difference of a rational and an irrational number is irrational
• The product and quotient of a non-zero rational and irrational number are irrational.
• √p is irrational when ‘p’ is a prime. For example, 7 is a prime number and √7 is irrational. The above statement can be proved by the method of “Proof by contradiction”.

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Proof by Contradiction

 In the method of contradiction, to check whether a statement is TRUE
  (i)  We assume that the given statement is TRUE.
  (ii) We arrive at some result which contradicts our assumption, thereby proving the contrary.
  Eg: Prove that √7 is irrational.
  Assumption: √7  is rational.
  Since it is rational √7 can be expressed as
  $\surd 7\; =\; a/b$, where a and b are co-prime Integers, b $\ne$ 0.
  On squaring, $a^2$$/b2=7$
  $\Rightarrow a^2=7b^2$.
Hence, 7 divides a. Then, there exists a number c such that a = 7c. Then, $a^2=49c^2$. Hence, $7b^2=49c^2$ or $b^2=7c^2$.
Hence 7 divides b. Since 7 is a common factor for both a and b, it contradicts our assumption that a and b are co-prime integers.
Hence, our initial assumption that √7  is rational is wrong. Therefore, √7 is irrational.

Revisiting Rational Numbers and Their Decimal Expansions

Rational Numbers

Rational numbers are numbers that can be written in the form p/q, where p and q are integers and $q\ne 0$.
Examples -1/2$,\; 4/5,1,0,-3$  and so on.

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Terminating and non terminating decimals

Terminating decimals are decimals that end at a certain point. Example: 0.2, 2.56 and so on.
Non-terminating decimals are decimals where the digits after the decimal point don’t terminate. Example: 0.333333….., 0.13135235343…
Non-terminating decimals can be :
a) Recurring – a part of the decimal repeats indefinitely (0.142857142857….)
b) Non-recurring – no part of the decimal repeats indefinitely. Example: $\pi =\mathrm{3.1415926535\dots }$

Check if a given rational number is terminating or not

If a/b is a rational number, then its decimal expansion would terminate if both of the following conditions are satisfied :
  a) The H.C.F of a and b is 1.
  b) b can be expressed as a prime factorization of 2 and 5 i.e $b=2^m\times 5^n$ where either m or n, or both can  = 0.
If the prime factorization of b contains any number other  than 2 or 5, then the decimal expansion of that number will be recurring

Example:

 1/40$=0.025$ is a terminating decimal,  as the H.C.F of 1 and 40 is 1, and the denominator (40) can be expressed as $2^3\times 5^1.$

$3/7$$=0.428571$ is a recurring decimal as the H.C.F of 3 and 7 is 1 and the denominator (7) is equal to $7^1$