SEBA ASSAM CLASS 10 MATHS SOLUTION FOR ENGLISH MEDIUM

SEBA / ASSAM CLASS 10 

MATHS SOLUTIONS 

CHAPTER 1- REAL NUMBERS 

FOR ENGLISH MEDIUM STUDENTS 

SEBA ASSAM CLASS 10 MATHS SOLUTION FOR ENGLISH MEDIUM 

SEBA / ASSAM CLASS 10 

MATHS SOLUTIONS 

CHAPTER 1- REAL NUMBERS 

FOR ENGLISH MEDIUM STUDENTS 

Page No 7: 

Question 1: Use Euclid’s division algorithm to find the HCF of: 

(i) 135 & 225 (ii) 196 & 38220 (iii) 867 and 255 

Answer: 

(i) 135 and 225 

Since 225 > 135, we apply the division lemma to 225 and 135 to obtain 

225 = 135 × 1 + 90 

Since remainder 90 ≠ 0, we apply the division lemma to 135 and 90 to obtain 

135 = 90 × 1 + 45 

We consider the new divisor 90 and new remainder 45, and apply the division lemma to obtain 90 = 2 × 45 + 0 

Since the remainder is zero, the process stops. 

Since the divisor at this stage is 45, 

Therefore, the HCF of 135 and 225 is 45. 

(ii)196 and 38220 

Since 38220 > 196, we apply the division lemma to 38220 and 196 to obtain 

38220 = 196 × 195 + 0 

Since the remainder is zero, the process stops. 

Since the divisor at this stage is 196, 

Therefore, HCF of 196 and 38220 is 196. 

(iii)867 and 255 

Since 867 > 255, we apply the division lemma to 867 and 255 to obtain 

867 = 255 × 3 + 102 

Since remainder 102 ≠ 0, we apply the division lemma to 255 and 102 to obtain 

255 = 102 × 2 + 51 

We consider the new divisor 102 and new remainder 51, and apply the division lemma to obtain 102 = 51 × 2 + 0 

Since the remainder is zero, the process stops. 

Since the divisor at this stage is 51, 

Therefore, HCF of 867 and 255 is 51. 

Question 2: Show that any positive odd integer is of the form 6q+1, or 6q+3, or 6q+5, where q is some  integer. 

Answer: Let ‘a’ be any positive integer and ‘b’ = 6. Then, by Euclid’s algorithm, 

a = 6q + r for some integer q ≥ 0, and r = 0, 1, 2, 3, 4, 5 because 0 ≤ r < 6. 

Therefore, a = 6q or 6q + 1 or 6q + 2 or 6q + 3 or 6q + 4 or 6q + 5 

Also, 6q + 1 = 2 × 3q + 1 = 2k1 + 1, where k1 is a positive integer

6q + 3 = (6q + 2) + 1 = 2 (3q + 1) + 1 = 2k2 + 1, where k2 is an integer 

6q + 5 = (6q + 4) + 1 = 2 (3q + 2) + 1 = 2k3 + 1, where k3 is an integer 

Clearly, 6q + 1, 6q + 3, 6q + 5 are of the form 2k + 1, where k is an integer. 

Therefore, 6q + 1, 6q + 3, 6q + 5 are not exactly divisible by 2. Hence, these expressions of numbers are odd  numbers. 

And therefore, any odd integer can be expressed in the form 6q + 1, or 6q + 3, or 6q + 5 

Question 3: An army contingent of 616 members is to march behind an army band of 32 members in a  parade. The two groups are to march in the same number of columns. What is the maximum number of  columns in which they can march? 

Answer: 

HCF (616, 32) will give the maximum number of columns in which they can march. 

We can use Euclid’s algorithm to find the HCF. 

616 = 32 × 19 + 8 

32 = 8 × 4 + 0 

The HCF (616, 32) is 8. 

Therefore, they can march in 8 columns each. 

Question 4: Use Euclid’s division lemma to show that the square of any positive integer is either of form  3m or 3m + 1 for some integer m. 

[Hint: Let x be any positive integer then it is of the form 3q, 3q + 1 or 3q + 2. Now square each of these and  show that they can be rewritten in the form 3m or 3m + 1.] 

Answer: 

Let a be any positive integer and b = 3. 

Then a = 3q + r for some integer q ≥ 0 

And r = 0, 1, 2 because 0 ≤ r < 3 

Therefore, a = 3q or 3q + 1 or 3q + 2 

Or, 

Where k1, k2, and k3 are some positive integers 

Hence, it can be said that the square of any positive integer is either of the form 3m or 3m + 1. 

Question 5: Use Euclid’s division lemma to show that the cube of any positive integer is of the form 9m,  9m + 1 or 9m + 8. 

Answer: 

Let a be any positive integer and b = 3 

a = 3q + r, where q ≥ 0 and 0 ≤ r < 3 

Therefore, every number can be represented as these three forms. There are three cases. Case 1: When a = 3q, 

Where m is an integer such that m =

Case 2: When a = 3q + 1, 

a3 = (3q +1)3 

a3 = 27q3 + 27q2 + 9q + 1 

a3 = 9(3q3 + 3q2 + q) + 1 

a3 = 9m + 1 

Where m is an integer such that m = (3q3 + 3q2 + q) 

Case 3: When a = 3q + 2, 

a3 = (3q +2)3

a3 = 27q3 + 54q2 + 36q + 8 

a3 = 9(3q3 + 6q2 + 4q) + 8 

a3 = 9m + 8 

Where m is an integer such that m = (3q3 + 6q2 + 4q) 

Therefore, the cube of any positive integer is of the form 9m, 9m + 1, or 9m + 8. 

Page No 11: 

Question 1: Express each number as product of its prime factors: 

Answer: 

Question 2: Find the LCM and HCF of the following pairs of integers and verify that LCM × HCF = product of  the two numbers. 

Answer: 

Hence, product of two numbers = HCF × LCM 

Hence, product of two numbers = HCF × LCM

Hence, product of two numbers = HCF × LCM 

Question 3: Find the LCM and HCF of the following integers by applying the prime factorisation method.

Answer: 

Question 4: Given that HCF (306, 657) = 9, find LCM (306, 657). 

Answer: 

Question 5: Check whether 6n can end with the digit 0 for any natural number n.

Answer: If any number ends with the digit 0, it should be divisible by 10 or in other words, it will also be  divisible by 2 and 5 as 10 = 2 × 5 

Prime factorization of 6n = (2 ×3)n 

It can be observed that 5 is not in the prime factorization of 6n. 

Hence, for any value of n, 6n will not be divisible by 5. 

Therefore, 6n cannot end with the digit 0 for any natural number n. 

Question 6: Explain why 7 × 11 × 13 + 13 and 7 × 6 × 5 × 4 × 3 × 2 × 1 + 5 are composite numbers. Answer: Numbers are of two types – prime and composite. Prime numbers can be divided by 1 and only  itself, whereas composite numbers have factors other than 1 and itself. 

It can be observed that 

7 × 11 × 13 + 13 = 13 × (7 × 11 + 1) = 13 × (77 + 1) 

= 13 × 78 

= 13 ×13 × 6 

The given expression has 6 and 13 as its factors. Therefore, it is a composite number. 7 × 6 × 5 × 4 × 3 × 2 × 1 + 5 = 5 ×(7 × 6 × 4 × 3 × 2 × 1 + 1) 

= 5 × (1008 + 1) 

= 5 ×1009 

1009 cannot be factorised further. Therefore, the given expression has 5 and 1009 as its factors. Hence, it is  a composite number. 

Question 7: There is a circular path around a sports field. Sonia takes 18 minutes to drive one round of the  field, while Ravi takes 12 minutes for the same. Suppose they both start at the same point and at the same  time, and go in the same direction. After how many minutes will they meet again at the starting point? Answer: It can be observed that Ravi takes lesser time than Sonia for completing 1 round of the circular  path. As they are going in the same direction, they will meet again at the same time when Ravi will have  completed 1 round of that circular path with respect to Sonia. And the total time taken for completing th is 1  round of circular path will be the LCM of time taken by Sonia and Ravi for completing 1 round of circular  path respectively i.e., LCM of 18 minutes and 12 minutes. 

18 = 2 × 3 × 3 

And, 12 = 2 × 2 × 3 

LCM of 12 and 18 = 2 × 2 × 3 × 3 = 36 

Therefore, Ravi and Sonia will meet together at the starting pointafter 36 minutes. Page No 14: 

Question 1: Prove that is irrational. 

Answer: 

Let is a rational number. 

Therefore, we can find two integers a, b (b ≠ 0) such that

Let a and b have a common factor other than 1. Then we can divide them by the common factor, and  assume that a and b are co-prime. 

Therefore, a2is divisible by 5 and it can be said that a is divisible by 5. 

Let a = 5k, where k is an integer 

This means that b2is divisible by 5 and hence, b is divisible by 5. 

This implies that a and b have 5 as a common factor. 

And this is a contradiction to the fact that a and b are co-prime. 

Hence, cannot be expressed as or it can be said that is irrational.

Question 2: Prove that is irrational. 

Answer: 

Let is rational. 

Therefore, we can find two integers a, b (b ≠ 0) such that 

Since a and b are integers, will also be rational and therefore, is rational. This contradicts the fact that is irrational. Hence, our assumption that is rational is false.  Therefore, is irrational. 

Question 3: Prove that the following are irrationals: 

Answer: 

Let is rational. 

Therefore, we can find two integers a, b (b ≠ 0) such that 

is rational as a and b are integers. 

Therefore, is rational which contradicts to the fact that is irrational. 

Hence, our assumption is false and is irrational. 

Let is rational. 

Therefore, we can find two integers a, b (b ≠ 0) such that 

for some integers a and b 

is rational as a and b are integers. 

Therefore, should be rational.

This contradicts the fact that is irrational. Therefore, our assumption that is rational is false.  Hence, is irrational. 

Let be rational. 

Therefore, we can find two integers a, b (b ≠ 0) such that 

Since a and b are integers, is also rational and hence, should be rational. This contradicts the fact  that is irrational. Therefore, our assumption is false and hence, is irrational. 

Page No 17: 

Question 1: Without actually performing the long division, state whether the following rational numbers will  have a terminating decimal expansion or a non-terminating repeating decimal expansion:

Answer: 

(i)

The denominator is of the form 5m. 

Hence, the decimal expansion of is terminating. 

(ii)

The denominator is of the form 2m. 

Hence, the decimal expansion of is terminating. 

(iii)

455 = 5 × 7 × 13 

Since the denominator is not in the form 2m × 5n, and it also contains 7 and 13 as its factors, its decimal  expansion will be non-terminating repeating. 

(iv)

1600 = 26× 52 

The denominator is of the form 2m × 5n. 

Hence, the decimal expansion of is terminating. 

(v)

Since the denominator is not in the form 2m × 5n, and it has 7 as its factor, the decimal expansion of is  non-terminating repeating. 

(vi)

The denominator is of the form 2m × 5n. 

Hence, the decimal expansion of is terminating. 

(vii)

Since the denominator is not of the form 2m × 5n, and it also has 7 as its factor, the decimal expansion  of is non-terminating repeating. 

(viii)

The denominator is of the form 5n. 

Hence, the decimal expansion of is terminating. 

(ix)

The denominator is of the form 2m × 5n. 

Hence, the decimal expansion of is terminating. 

(x)

Since the denominator is not of the form 2m × 5n, and it also has 3 as its factors, the decimal expansion  of is non-terminating repeating. 

Page No 18: 

Question 2: Write down the decimal expansions of those rational numbers in Question 1 above which have  terminating decimal expansions. 

Answer:

(viii)

Question 3: 

The following real numbers have decimal expansions as given below. In each case, decide whether they are  rational or not. If they are rational, and of the form , what can you say about the prime factor of q? (i) 43.123456789 (ii) 0.120120012000120000… (iii)

Answer: 

(i) 43.123456789 

Since this number has a terminating decimal expansion, it is a rational number of the form and q is of the  form

i.e., the prime factors of q will be either 2 or 5 or both. 

(ii) 0.120120012000120000 … 

The decimal expansion is neither terminating nor recurring. Therefore, the given number is an irrational  number. 

(iii)

Since the decimal expansion is non-terminating recurring, the given number is a rational number of the  form and q is not of the form i.e., the prime factors of q will also have a factor other than 2 or 5. 

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