# Maths

## Dividing Fractions

### Dividing Whole numbers by Fractions:

- When a whole number is divided by a fraction, whole number is to be multiplied by the reciprocal of that fraction.
- In generalise form, for any whole number ‘a’ and fraction b/c

- Reciprocal of a fraction, fraction are said to be reciprocal when we simply reverse the fraction i.e numerator becomes denominator and denominator becomes numerator. Two fractions are said to be reciprocal of each other if their product is 1.
- In generalise form, for any fraction a/b

**Example **

Divide 40 by 6/4

**Solution**

We have, 40 ÷ 6/4

In order to divide a whole number by a Fraction, we need to multiply the whole number with the reciprocal of that Fraction.

We have to multiply Whole number by Reciprocal of that Fraction

40 x 4/6 (Since, Reciprocal of 6/4 is 4/6)

Simplifying the given Fraction,

HCF of 160 and 6 is 2

__Dividing Fraction by Whole Number:__

- When a fraction is divided by a whole number, fraction is to be multiplied by the reciprocal of that whole number.
- In generalise form, for any fraction a/b and whole number ‘c’

**Example**

Divide 3/7 by 6

**Solution**

We have, 3/7 ÷ 6

In order to divide a Fraction by a whole number

We have to multiply Fraction with Reciprocal of that whole number

__Dividing Fraction by Fractions__

- When a fraction is divided by another fraction, the first fraction is multiplied by the reciprocal of second fraction.

**Example**

In order to divide a Fraction by another Fraction

We have to multiply First Fraction with Reciprocal of the second Fraction

### Division of Mixed Fraction by Improper or Proper Fractions

- When a mixed fraction is divide by a proper or improper fraction, convert mixed fraction into improper fraction and then divide them.

**Example**

In order to divide a Fraction by another Fraction

We have to multiply First Fraction with Reciprocal of the second Fraction

### Learn More..

## Properties of Integers | Closure, Commutative, Associative, Distributive

Properties of Integers, deals with various concepts which are as under:-

- Closure Property of Integers
- Commutative Property of Integers
- Associative Property of Integers
- Distributive Property of Integers
- Additive Identity
- Multiplicative Identity of Integers

__Closure Property of Integers__

__Closure Property under Addition of Integers__

If we add any two integers, the result obtained on adding the two integers, is always an integer. So we can say, that integers are closed under addition.

Let us say ‘a’ and ‘b’ are two integers, either positive or negative. When we add the two integers, their result would always be an integer, i.e (a + b) would always be an integer.

**Example –**

State whether (– 11) + 2 is closed under addition

**Solution**

– 11 + 2

– 9

Since both -11 and 2 are integers, and their sum, i.e (-9) is also an integer, we can say that integers are closed under addition.

__Closure Property under Subtraction of Integers__

If we subtract any two integers the result is always an integer, so we can say that integers are closed under subtraction.

Let us say ‘a’ and ‘b’ are two integers either positive or negative, their result should always be an integer, i.e (a + b) would always be an integer.

**Example –**

State whether (24 – 12) is closed under subtraction

**Solution –**

24 – 12

12

Since both 24 and -12 are integers, and their difference, i.e (12) is also an integer, we can say that integers are closed under subtraction.

__Closure Property under Multiplication of Integers__:

If we multiply any two integers the result is always an integer, so we can say that integers are closed under multiplication.

Let us say ‘a’ and ‘b’ are two integers either positive or negative, and if multiply it, their result should always be an integer, i.e [(-a) x b] and [a x (–b)] would always be an integer.

**Example –**

Show that (-30) x 11 closed under multiplication

**Solution – **

– 30 x 11

-330

Since both -30 and 11 are integers, and their product, i.e (-330) is also an integer, we can say that integers are closed under multiplication.

__Closure Property under Division of Integers__:

If we divide any two integers the result is not necessarily an integer, so we can say that integers are not closed under division.

Let us say ‘a’ and ‘b’ are two integers, and if we divide them, their result ( a ÷ b ) is not necessarily an integer.

**Example – **

State whether (14) ÷ 5 is closed under division.

**Solution – **

(14) ÷ 5

8

Since both 14 and 5 are integers, but (14) ÷ 5 = 2.8 which is not an integer. Hence, we can say that integers are not closed under division.

__Commutative Property of Integers__

__Commutative Property under Addition of Integers:__

- If we add two whole numbers say ‘a’ and ‘b’ the answer will always same, i.e if we add (2+3) = (3+2) = 5. So whole numbers are commutative under addition. Similarly if we apply this to integers, (-5+3) = (3+(-5))= -2, it also hold for all integers. So we can say that commutative property holds under addition for all integers.
- In generalise form for any two integers ‘a’ and ‘b’

a + b = b + a

**Example –**

Show that -32 and 23 follow commutative property under addition.

**Solution –**

L.H.S = -32 + 23 = – 9

R.H.S = 23 + (-32) = 23 – 32 = – 9

So, L.H.S = R.H.S, i.e a + b = b + a

This means the two integers follow commutative property under addition.

__Commutative Property under Subtraction of Integers__:

- On contradictory, commutative property will not hold for subtraction of whole number say (5 – 6) is not equal to (6 – 5). Let us consider for integers (4) and (-1), the difference of two numbers are not always same.

{4 – (-1) = 4 + 1= 5} and {(-1) – 4 = – 1 – 4 = -5}, so the difference of two integers are 5 and (-5) which are not equal so we can say that commutative property will not hold for subtraction of integers.

- In generalise form for any two integers ‘a’ and ‘b’

(a – b) ≠ (b – a)

**Example –**

Check whether -88 and 22 follow commutative property under subtraction.

**Solution –**

L.H.S = -88 – 22 = – 110

R.H.S = 22 – (-88) = 22 + 88 = 110

So, L.H.S ≠ R.H.S

This means the two integers do not follow commutative property under subtraction.

__Commutative Property under Multiplication of Integers__:

- If we multiply two whole numbers say ‘a’ and ‘b’ the answer will always same, i.e if we multiply (2×3) = (3×2) = 6. So whole numbers are commutative under multiplication. Similarly if we apply this to integers, (-5×3) = (3x(-5))= -6, it also hold true for all integers. So we can say that commutative property holds under multiplication for all integers.
- In generalise form for any two integers ‘a’ and ‘b’

a x b = b x a

**Example –**

Show that any two integers follow commutative property under multiplication.

Let us assume that the two integers are (-12) and 20,

L.H.S = (-12) x 20

= -240

R.H.S = 20 x (-12)

= -240

So, L.H.S = R.H.S, i.e ‘a x b’ = ‘b x a’

This means the two integers follow commutative property under multiplication.

__Commutative Property under Division of Integers__:

- Commutative property will not hold true for division of whole number say (12 ÷ 6) is not equal to (6 ÷ 12). Let us consider for integers say, (-14) and (7), the division of two numbers are not always same.

[(-14) ÷ 7 = -2] and [7 ÷ (-14) = -0.5}, so the result of division of two integers are not equal so we can say that commutative property will not hold for division of integers.

- In generalise form for any two integers ‘a’ and ‘b’

(a ÷ b) ≠ (b ÷ a)

**Example – **

State whether (-12) and (-3) follow commutative law under division?

**Solution – **

L.H.S = (-12) ÷ (-3) = 4

R.H.S = (-3) ÷ (-12) = 25

So, L.H.S ≠ R.H.S; i.e (a ÷ b) ≠ (b ÷ a)

This means the two integers do not follow commutative property under division.

__Associative Property of Integers__

__Associative Property under Addition of Integers__:

- As commutative property hold for addition similarly associative property also holds for addition.
- In generalize form for any three integers say ‘a’, ’b’ and ‘c’

a + (b + c) = (a + b) + c

**Example – **

Show that (-6), (-1) and (3) are associative under addition.

**Solution – **

L.H.S = – 6 + ( -1 + 3)

= – 6 + 2

= – 4

R.H.S = (- 6 + (-1)) + 3

= (- 6 – 1) + 3

= -7 + 3

= -4

So, L.H.S = R.H.S, i.e a + (b + c) = (a + b) + c

This means all three integers follow associative property under addition.

__Associative Property under Subtraction of Integers__:

- On contradictory, as commutative property does not hold for subtraction similarly associative property also does not hold for subtraction of integers.
- In generalize form for any three integers say ‘a’, ’b’ and ‘c’

a – (b – c) ≠ (a – b) – c

**Example –**

Check whether (-6), (-1) and 3 follow associative property under subtraction.

**Solution –**

L.H.S = -6 – (-1 -3)

= -6 – (-4)

= -6 +4

= -2

R.H.S = (-6 – (-1)) – 3

= (-6 +1) – 3

= -5 -3

= -8

So, L.H.S ≠ R.H.S

This means all three integers do not follow associative property under subtraction.

__Associative Property under Multiplication of Integers__:

- As commutative property hold true for multiplication similarly associative property also holds true for multiplication.
- The associative property of multiplication does not depend on the grouping of the integers.
- In generalize form for any three integers say ‘a’, ’b’ and ‘c’

a x (b x c) = (a x b) x c

**Example –**

Show that (-2), (-3) and 4 hold associative property for multiplication

**Solution – **

L.H.S = (-2) x ( -3 x 4)

= -2 x -12

= 24

R.H.S = (-2 x -3) x 4

= 6 x 4

= 24

So, L.H.S = R.H.S; i.e a x (b x c) = (a x b) x c

This means all three integers follow associative property under multiplication.

__Distributive Property of Integers__:

**Distributive properties of multiplication of integers are divided into two categories, **over** addition **and** over subtraction.**

1. Distributivity of multiplication over addition hold true for all integers.

In generalize form for any three integers say ‘a’, ’b’ and ‘c’

a x (b + c) = (a x b) + (a x c)

**Example –**

Show that (-2), 3 and 5 follow distributive property of multiplication over addition.

**Solution – **

L.H.S = -2 x (3 + 5)

= -2 x 8

= -16

R.H.S = (-2 x 3) + (-2 x 5)

= -6 + (-10)

= -6 -10

= -16

So, L.H.S = R.H.S; i.e a x (b + c) = (a x b) + (a x c)

This means that distributive property of multiplication over addition holds true for all integers.

2. Distributivity of multiplication over subtraction hold true for all integers.

In generalize form for any three integers say ‘a’, ’b’ and ‘c’

a x (b – c) = (a x b) – (a x c)

**Example – **

Show that (-5), (-4) and (-2) follow distributive property of multiplication over subtraction.

L.H.S = -5 x (-4 – (-2))

= -5 x (-4 + 2)

= -5 x -2

= 10

R.H.S = (-5 x -4) – (-5 x -2)

= 20 – 10

= 10

So, L.H.S = R.H.S; i.e a x (b – c) = (a x b) – (a x c)

This means that distributive property of multiplication over subtraction holds true for all integers.

__Additive Identity__:

When we add zero to any whole number we get the same number, so zero is additive identity for whole numbers. Similarly if we add zero to any integer we get the back the same integer whether the integer is positive or negative. In general for any integer ‘a’

a + 0 = 0 + a = a

__Multiplicative Identity of Integers__:

- When we multiply any positive or negative integer by 1 the answer will remains same the integer only.
- In generalise form, for any integer ‘a’

a x 1 = 1 x a = a

### Learn More..

## Convert Percent to Fraction | Maths Grade 7

### Convert Percent to Fraction

**Step 1** – In order to convert Percent to Fraction, we divide the Percentage by 100, and remove the sign of Percentage (%).

**Step 2** – Simplify the Fraction

### Convert Percent to Fraction Examples

**Example 1**

Convert 50 % into a Fraction:

**Explanation**

50 % = 50/100

On Simplifying, 50/100

HCF of 50 and 100 is 50

Divide both 50 and 100 by their HCF

**Example 2**

Convert 40 % into a Fraction:

**Explanation**

40 % = 40/100

On Simplifying, 40/100

HCF of 40 and 100 is 20

Divide both 40 and 100 by their HCF

**Example 3**

Convert 65 % into a Fraction:

**Explanation**

65 % = 65/100

On Simplifying, 65/100

HCF of 65 and 100 is 5

Divide both 65 and 100 by their HCF

**Example 4**

Convert 80 % into a Fraction:

**Explanation**

80 % = 80/100

On Simplifying, 80/100

HCF of 80 and 100 is 20

Divide both 80 and 100 by their HCF

**Example 5**

Convert 75 % into a Fraction:

**Explanation**

75 % = 75/100

On Simplifying, 75/100

HCF of 75 and 100 is 25

Divide both 75 and 100 by their HCF

**Example 6**

Convert 88 % into a Fraction:

**Explanation**

88 % = 88/100

On Simplifying, 88/100

HCF of 88 and 100 is 4

Divide both 88 and 100 by their HCF

**Example 7**

Convert 90 % into a Fraction:

**Explanation**

90 % = 90/100

On Simplifying, 90/100

HCF of 90 and 100 is 10

Divide both 90 and 100 by their HCF

**Example 8**

Convert 76 % into a Fraction:

**Explanation**

76 % = 76/100

On Simplifying, 76/100

HCF of 76 and 100 is 4

Divide both 76 and 100 by their HCF

### Learn More..** **

## Prime Numbers | Composite Numbers | Maths Class 4

**Prime Numbers **

Prime number is a natural number greater than 1 that has no positive divisors other than 1 and itself

In other words, we can say prime numbers don’t have any factor other than 1 and itself.

**Composite Numbers**

Composite numbers are divisible by one or more numbers other than 1 and itself.

In other words, we can say that numbers having more than two factors are composite numbers.

**Examples of Prime Numbers**

**Example 1**

Is 2 is a Prime number?

**Solution**

Factors of 2 are

2 ÷ 1

2 is not divisible by any other number, other than 1 and itself

therefore, 2 is Prime number.

**Example 2**

Is 6 is a Prime number?

**Solution**

Factors of 6 are

6 ÷ 1 = 6

6 ÷ 2 = 3

6 ÷ 3 = 2

6 ÷ 6 = 1

6 is divisible by 1 , 2 , 3 and 6

therefore, 6 is not a Prime number.

**Example 3**

Is 7 is a Prime number?

**Solution**

Factors of 7 are 7 x 1

7 is not divisible by any other number, other than 1 and itself

therefore, 7 is Prime number.

**Example 4**

Is 12 is a Prime number?

**Solution**

Factors of 12 are

12 ÷ 1 = 12

12 ÷ 2 = 6

12 ÷ 3 = 4

12 ÷ 4 = 3

12 ÷ 6 = 2

12 ÷ 12 = 1

12 is divisible by 1, 2, 3, 4, 6 and 12

therefore, 12 is not a Prime number.

**Examples of Composite Numbers**

**Example 1**

Is 4 is a Composite number?

**Solution**

Factors of 4 are

4 ÷ 1 = 4

4 ÷ 2 = 2

Factors of 4 are 1 , 4 and 2

Therefore, 4 has more than two factors.

Hence, 4 is a Composite number.

**Example 2**

Is 2 is a Composite number?

**Solution**

Factors of 2 are

2 ÷ 1 = 2

Factors of 2 are 1 and 2

Therefore, 2 does not have more than two factors.

Hence, 2 is not a Composite number.

**Example 3**

Is 9 is a Composite number?

**Solution**

Factors of 9 are 1 x 9 , 3 x 3 and 9 x 1

Factors of 9 are 1 , 3 and 9

Therefore, 9 has more than two factors.

Hence, 9 is a Composite number.

**Example 4**

Is 13 is a Composite number?

**Solution**

Factors of 13 are 1 x 13

Factors of 13 are 1 and 13

Therefore, 13 does not have more than two factors.

Hence, 13 is not a Composite number.

**Learn More..**

## Subtraction of Like Fractions | Subtraction of Unlike Fractions

Subtraction of Like Fractions – To subtracts **Like Fractions**, we subtract the numerators and write the difference over the same denominator.

Subtraction of Unlike Fractions – To subtracts **Unlike Fractions**, first we have to change the Unlike Fractions, into equivalent Like Fractions, and then subtract the two equivalent Like Fractions

**Subtraction of Like Fractions Examples**

**QUESTION – 1**

Find the difference of 10/6 and 7/6 and reduce to its lowest term.

[Read more…] about Subtraction of Like Fractions | Subtraction of Unlike Fractions

## Comparing Fractions

**Comparing Fractions can be divided in two categories: **

- Comparison of Like Fractions (Comparing fractions with same denominators)
- Comparison of Unlike Fractions (Comparing fractions with different denominators)

First Method : By Converting Given Fractions into Like Fractions

Second Method : By Cross Multiplication Method

**1. Comparison of Like Fractions**

(Comparing fractions with same denominators)

**QUESTION**

Compare 7/3 and 4/3

**EXPLANATION**

7/3 and 4/3 are Like Fraction as Denominator of both the Fractions is same i.e, 3

In case of Like Fraction, the Fraction with the higher numerator is Higher

On Comparing the Numerators, we find

7 > 4

Hence, 7/3 > 4/3

**2. Comparison of Unlike Fractions**

(Comparing fractions with different denominators)

**QUESTION**

Compare 2/3 and 1/2

**EXPLANATION**

2/3 and 1/2 are Unlike Fractions as Denominator of both the Fractions is different i.e, 3 and 2

To compare Unlike Fractions we have two methods:

**First Method : By Converting Given Fractions into Like Fractions**

Given Fractions :

2/3 and 1/2

Taking LCM of the Denominator of both the Fractions.

i.e, LCM of 3 and 2 is 6

To change the Unlike Fractions into Like Fractions

We have to multiply the Numerator and Denominator of the Given Fraction by a number such that the Denominator of the given Fraction becomes equal to its LCM i.e, 6

]

Now the Given Fractions are Like Fraction as their Denominator become same.

On Comparing their Numerators, we find

4 > 3

Therefore, 4/6 > 3/6

Hence, 2/3 > 1/2

**Second Method : By Cross Multiplication Method **

On Cross multiplying 2/3 and 1/2

In Cross Multiplication Method we multiply the Numerator of First Fraction namely 2 by the Denominator of Second Fraction namely 2 i.e,

2 x 2 = 4

Then, we multiply the Numerator of Second Fraction namely 1 by the Denominator of First Fraction namely 3 i.e,

1 x 3 = 3

Since, 4 > 3

Therefore, 2/3 > 1/2

### Learn More..

- Proper Fraction | Improper Fraction | Mixed Fraction
- Like Fractions & Unlike Fractions
- Unit Fraction
- Fraction in Simplest Form
- Finding Fraction of a Whole Number
- What is an Equivalent Fraction
- Finding Equivalent Fraction with given Denominator
- Finding Equivalent Fraction with given Numerator
- Convert Mixed Fraction to Improper Fraction
- Convert Improper Fraction to Mixed Fraction
- Addition of Like Fractions and Unlike Fractions
- Subtraction of Like Fractions or Unlike Fractions

## What are Consecutive Numbers – Consecutive Numbers Example

**What are Consecutive Numbers ? **

What are Consecutive Numbers ? This question often comes to the mind of Maths students in early classes. Consecutive numbers are numbers, that follow each other , in the order of smallest to largest.

In other words, we can say that consecutive number of any given number is obtained **by adding 1 to that number.**

[Read more…] about What are Consecutive Numbers – Consecutive Numbers Example