Class 10 Exam  >  Class 10 Notes  >  RD Sharma Solutions for Class 10 Mathematics  >  Chapter 1 - Real Numbers, RD Sharma Solutions - (Part - 2)

Chapter 1 - Real Numbers, RD Sharma Solutions - (Part - 2) | RD Sharma Solutions for Class 10 Mathematics PDF Download

Page No 1.11

Q.11. Show that any positive odd integer is of the form 6q + 1 or, 6q + 3 or, 6q + 5, where q is some integer.
Ans. To Show: That any positive odd integer is of the form 6q + 1 or 6q + 3 or 6q + 5 where q is any some integer.
Proof: Let a be any odd positive integer and = 6.
Then, there exists integers q and r such that
a = 6q + r, 0 ≤ r < 6 (by division algorithm)
a = 6q or 6q + 1 or 6q + 2 or 6q + 3 or 6q + 4
But 6q or 6q + 2 or 6q + 4 are even positive integers.
So, a = 6q + 1 or 6q + 3 or 6q + 5
Hence it is proved that any positive odd integer is of the form 6q + 1 or 6q + 3 or 6q + 5, where q is any some integer. 

Q.12. Show that the square of  any positive integer cannot be of the form 6m + 2  or 6m + 5  for any integer m.
Ans. Suppose a be any arbitrary positive integer, then by Euclid's division algorithm, corresponding to the positive integers a and 6, there exists non-negative integers a and r such that
a = 6+ r, where 0r<6 

⇒ a2 = (6q + r)2 = 36q2 + r2 + 12qr
⇒ a2 = 6(6q2 + 2qr) + r2 ...(1) where, 0 ≤ r < 6
Case: 1
When r = 0.
Putting r = 0 in (1), we get 

a2 = 6(6q)2 = 6m
Where, m = 6q2 is an integer
Case: 2
When r = 1.
Putting r = 1 in (1), we get

a2 = 6(6q2 + 2q) + 1
⇒ a2 = 6m + 1
where, m = (6q2 + 2q) is an integer
Case: 3
When r = 2.
Putting r = 2 in (1), we get 
a2 = 6(6q2 + 4q) + 4
⇒ a2 = 6m + 4
where, m = (6q2 + 4q) is an integer
Case: 4
When r = 3.
Putting r = 3 in (1), we get

a2 = 6(6q2 + 6q) + 9
⇒ a2 = 6(6q2 + 6q) + 6 + 3
⇒ a2 = 6(6q2 + 6q + 1) + 3
⇒ a2 = 6m + 3
where, m = (6q2 + 6q + 1) is an integer
Case: 5
When r = 4
Putting r = 4 in (1), we get

a2 = 6(6q2 + 8q) + 16
⇒ a2 = 6(6q2 + 8q) + 12 + 4
⇒ a2 = 6(6q2 + 8q + 2) + 4
⇒ a2 = 6m + 4
where, m = (6q2 + 8q + 2) is an integer
Case: 6
When r = 5.
Putting r = 5 in (1), we get

a2 = 6(6q2 + 10q) + 25
⇒ a2 = 6(6q2 + 10q) + 24 + 1
⇒ a2 = 6(6q2 + 10q + 4) + 1
⇒ a2 = 6m + 1
where, m = (6q2 + 10q + 1) is an integer
Hence, the square of any positive integer cannot be of the form 6m + 2 or 6m + 5.

Q.13. Show that the cube of a positive  integer is of the form 6q + rwhere q is an a integer and r = 0, 1, 2, 3, 4, 5.
Ans. Suppose a be any arbitrary positive integer, then by Euclid's division algorithm, corresponding to the positive integers a and 6, there exists non-negative integers a and r such that
a = 6+ r, where 0 ≤ r < 6

⇒ a3 = (6q + r)3 = 216q3 + r3 + 3 x 6q x r(6q + r)⇒ a3 = 6(216q3 + 108q2r + 18qr2) + r3 ....(1) where, 0 ≤ r < 6
Case: 1
When r = 0.
Putting r = 0 in (1), we get
a3 = 216q= 6(36q3) = 6m
where, m = 36q3 is an integer
Case: 2
When r = 1.
Putting r = 1 in (1), we  get 
a3 = (216q3 + 108q2 + 18q) + 1
⇒ a3 = 6(36q3 + 18q2 + 3q) + 1
⇒ a3 = 6m + 1
where, m = 36q3 + 18q2 + 3q) is an integer
Case: 3
When r = 2.
Putting r = 2 in (1), we get 

a3 = (216q3 + 216q2 + 72q) + 8
a3 = (216q3 + 216q2 + 72q + 6) + 2
⇒ a3 = 6(36q3 + 36q2 + 12q + 1) + 2
⇒ a3 = 6m + 2
where, m = (36q3 + 36q2 + 12q + 1) is an integer
Case: 4
When r = 3.
Putting r = 3 in (1), we get 

a3 = (216q3 + 324q2 + 162q) + 27
a3 = (216q3 + 324q2 + 162q + 24) + 3
⇒ a3 = 6(36q3 + 54q2 + 27q + 4) + 3
⇒ a3 = 6m + 3
where, m = (36q3 + 54q2 + 27q + 4) is an integer
Case: 5
When r = 4
Put r = 4 in (1), we get
a3 = (216q3 + 432q2 + 288q) + 64
a3 = (36q3 + 72q2 + 48q + 60) + 4
⇒ a3 = 6(36q3 + 72q2 + 48q + 10) + 4
⇒ a3 = 6m + 4
where, m = (36q3 + 72q2 + 48q + 10) is an integer

Case: 6
When r = 5.
Putting r = 5 in (1), we get

a3 = 216q3 + 540q2 + 450q + 125
a3 = 6(36q3 + 90q2 + 75q + 20) + 5
⇒ a3 = 6m + 5
where, m = (36q3 + 90q2 + 75q + 20) is an integer

Hence, the cube of any positive integer of the form 6q + r, where q is an integer and r = 0, 1, 2, 3, 4, 5.

Q.14. Show that one and only one out of n, n + 4, n + 8 , n +12 and n + 16 is divisible by 5, where n is any positive integer.
Ans. 
Consider the numbers n, (n + 4), (n + 8), (n + 12) and (n + 16),
Suppose n = 5q + r, where 0 ≤ r < 5
n = 5q, 5q + 1, 5q + 2, 5q + 3, 5q + 4
(By Euclid's division algorithm)
Case: 1 
When n = 5q.
n = 5q is divisible by 5.
n + 4 = 5q + 4 is not divisible by 5.
n + 8 = 5q + 5 + 5 + 3 = 5(q + 1) + 3 is not divisible by 5.
n + 12 = 5q + 10 + 2 = 5(q + 2) + 2 is not divisible by 5.
n + 16 = 5q + 15 + 1 = 5(q + 3) + 1 is not divisible by 5.
Case: 2 
When n = 5q + 1.
n = 5q + 1 is not divisible by 5.
n + 4 = 5q + 1 + 4 = 5(q + 1) is divisible by 5.
n + 8 = 5q + 1 + 5 + 3 = 5(q + 1) + 4 is not divisible by 5.
n + 12 = 5q + 1 + 12 = 5(q + 2) + 3 is not divisible by 5.
n + 16 = 5q + 1 + 16 = 5(q + 3) + 2 is not divisible by 5.
Case: 3 
When n = 5q + 2.
n = 5q + 2 is not divisible by 5.
n + 4 = 5q + 2 + 4 = 5(q + 1) + 1 is not divisible by 5.
n + 8 = 5q + 2 + 8 = 5(q + 2) is divisible by 5.
n + 12 = 5q + 2 + 12 = 5(q + 2) + 4 is not divisible by 5.
n + 16 = 5q + 2 + 16 = 5(q + 3) + 3 is not divisible by 5.
Case: 4 
When n = 5q + 3.
n = 5q + 3 is not divisible by 5.
n + 4 = 5q + 3 + 4 = 5(q + 1) + 2  is not divisible by 5.
n + 8 = 5q + 3 + 8 = 5(q + 2) + 1 is not divisible by 5.
n + 12 = 5q + 3 + 12 = 5(q + 3) is divisible by 5.
n + 16 = 5q + 3 + 16 = 5(q + 3) + 4 is not divisible by 5.
Case: 5 
When n = 5q + 4.
n = 5q + 4 is not divisible by 5.
n + 4 = 5q + 4 + 4 = 5(q + 1) + 3  is not divisible by 5.
n + 8 = 5q + 4 + 8 = 5(q + 2) + 2 is not divisible by 5.
n + 12 = 5q + 4 + 12 = 5(q + 3) + 1 is not divisible by 5.
n + 16 = 5q + 4 + 16 = 5(q + 4) is divisible by 5.
Hence, in each case, one and only one out of n, n + 4, n + 8, n + 12 and n + 16 is divisible by 5.

Q.15. Show that the square of an odd positive integer can be of the form 6q + 1 or  6q + 3 for some integer q.
Ans. It is known that any positive integer can be written in the form of 6m, 6m + 1, 6m + 2, 6m + 3, 6m + 4, 6m + 5 for some integer m.
Thus, an odd positive integer can be of the form  6m + 1,6m + 3,6m + 5.
We have, (6m + 1)= 36m+ 12m + 1 = 6(6m2 + 2m) + 1 = 6q + 1, where q = 6m2 + 2m is an integer
(6m + 3)= 36m2 + 36m + 9 = 6(6m2 + 6m + 1) + 3 = 6q + 3, where q = 6m2 + 6m + 1 is an integer
(6m + 5)= 36m2 + 60m + 25 = 6(6m2 + 10m + 4) + 1 = 6q + 1, where q = 6m2 + 10m + 4 is an integer
Thus, the square of an odd positive integer can be of the form 6q + 1 or 6q + 3 for some integer q.

Q.16. A positive integer is of the form 3q + 1 ,q being a natural number. Can you write its square in any form other than 3m + 1,3m or 3m + 2 for some integer m ? Justify your answer.
Ans. By Euclid's lemma, b = aq + r, 0 ≤ r < a.
Here, b is a positive integer and a = 3.
∴ b = 3q + r, for 0 ≤ r < 3
This must be in the form 3q, 3q + 1 or 3q + 2.
Now,
(3q)= 9q2 = 3m, where m=3q2
(3q + 1)= 9q2 + 6q + 1 = 3(3q2 + 2q) + 1 = 3m + m+1, where m = 3q+ 4q + 1
Therefore, the square of a positive integer 3q + 1 is always in the form of 3m or 3m + 1 for some integer m.

Q.17. Show that the square of any positive integer cannot be of the form 3m + 2, where m is a natural number.
Ans. By Euclid's lemma, b = aq + r, 0 ≤ r < a.
Here, b is a positive integer and a = 3.
∴ b = 3q + r, for 0 ≤ r < 3
This must be in the form 3q, 3q + 1 or 3q + 2.
Now,
(3q)= 9q2 = 3m, where m = 3q2
(3q + 1)= 9q2 + 6q + 1 = 3(3q+ 2q) + 1 = 3m + 1, where m = 3q2 + 2q
(3q + 2)= 9q2 + 12q + 4 = 3(3q2 + 4q + 1) + 1 = 3m + 1, where m = 3q2 + 4q + 1
Therefore, the square of a positive integer cannot be of the form 3m + 2, where m is a natural number.

The document Chapter 1 - Real Numbers, RD Sharma Solutions - (Part - 2) | RD Sharma Solutions for Class 10 Mathematics is a part of the Class 10 Course RD Sharma Solutions for Class 10 Mathematics.
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FAQs on Chapter 1 - Real Numbers, RD Sharma Solutions - (Part - 2) - RD Sharma Solutions for Class 10 Mathematics

1. What are real numbers according to RD Sharma Solutions?
Ans. Real numbers, as per RD Sharma Solutions, include all rational and irrational numbers, such as integers, fractions, decimals, and square roots.
2. How are real numbers classified in RD Sharma Solutions?
Ans. Real numbers are classified into rational numbers and irrational numbers in RD Sharma Solutions. Rational numbers can be expressed as fractions, while irrational numbers cannot be expressed as fractions.
3. What are some examples of real numbers in RD Sharma Solutions?
Ans. Examples of real numbers in RD Sharma Solutions include 3, -0.25, 1/2, √2, and π. These numbers can be represented on a number line.
4. How are real numbers used in solving mathematical problems in RD Sharma Solutions?
Ans. Real numbers are used in RD Sharma Solutions to solve various mathematical problems, such as equations, inequalities, and geometric calculations. They form the basis for algebraic operations.
5. Why are real numbers important in mathematics according to RD Sharma Solutions?
Ans. Real numbers play a crucial role in mathematics as they provide a foundation for numerical calculations and problem-solving. They are essential in various branches of mathematics, including algebra, geometry, and calculus.
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