Introduction
In Mathematics, we frequently come across simple equations to be solved. For example,
the equation x + 2 = 13 (1)
is solved when x = 11, because this value of x satisfies the given equation. The solution 11 is a natural number. On the other hand, for the equation x + 5 = 5 (2)
the solution gives the whole number 0 (zero). If we consider only natural numbers, equation (2) cannot be solved. To solve equations like (2), we added the number zero to the collection of natural numbers and obtained the whole numbers. Even whole numbers will not be sufficient to solve equations of type
x + 18 = 5 (3)
Do you see ‘why’? We require the number –13 which is not a whole number. This led us to think of integers, (positive and negative). Note that the positive integers correspond to natural numbers. One may think that we have enough numbers to solve all simple equations with the available list of integers. Now consider the equations
2x = 3 (4)
5x + 7 = 0 (5)
for which we cannot find a solution from the integers. (Check this) We need the numbers \(\frac{3}{2}\) to solve equation (4) and \(\frac{-7}{5}\) to solve equation (5). This leads us to the collection of rational numbers.
We have already seen basic operations on rational numbers. We now try to explore some properties of operations on the different types of numbers seen so far.
Closure Properties of Rational Numbers
(i) Whole numbers
Let us revisit the closure property for all the operations on whole numbers in brief.
Check for closure property under all the four operations for natural numbers.
(ii) Integers Let us now recall the operations under which integers are closed.
You have seen that whole numbers are closed under addition and multiplication but not under subtraction and division. However, integers are closed under addition, subtraction and multiplication but not under division.
(iii) Rational numbers
Recall that a number which can be written in the form \(\frac{p}{q}\) , where p and q are integers and q ≠ 0 is called a rational number. For example, \(\frac{-2}{3}\), \(\frac{6}{7}\) , \(\frac{-9}{5}\) are all rational numbers. Since the numbers 0, –2, 4 can be written in the form \(\frac{p}{q}\) , they are also rational numbers. (Check it!)
\(\frac{3}{8}+\frac{(-5)}{7}=\frac{21+(-40)}{56}=\frac{-19}{56}\) (a rational number)
\(\frac{-3}{8}+\frac{(-4)}{7}=\frac{-15+(-32)}{40}=..\) Is it a rational number?
\(\frac{4}{7}+\frac{6}{11}=..\) Is it a rational number?
We find that sum of two rational numbers is again a rational number. Check it for a few more pairs of rational numbers.
b.We say that rational numbers are closed under addition. That is, for any two rational numbers a and b, a + b is also a rational number.Will the difference of two rational numbers be again a rational number? We have,
\(\frac{-5}{7}-\frac{2}{3}=\frac{-5\times 3-2\times 7}{21}=\frac{-29}{21}\) (a rational number)
\(\frac{5}{7}-\frac{4}{5}=\frac{25-32}{40}=...\) Is it a rational number?
\(\frac{3}{7}-(\frac{-8}{5})=...\) Is it a rational number?
Try this for some more pairs of rational numbers. We find that rational numbers are closed under subtraction. That is, for any two rational numbers a and b, a – b is also a rational number.
c.Let us now see the product of two rational numbers.
\(\frac{-2}{3}\times \frac{4}{5}=\frac{-8}{15};\frac{3}{7}\times \frac{2}{5}=\frac{6}{35}\) (both the products are rational numbers)
\(\frac{-4}{5}\times \frac{-6}{11}=...\) Is it a rational number?
Take some more pairs of rational numbers and check that their product is again a rational number. We say that rational numbers are closed under multiplication. That is, for any two rational numbers a and b, a × b is also a rational number
d.We note that
\(\frac{-5}{3}\div \frac{2}{5}=\frac{-25}{6}\) (a rational number)
\(\frac{2}{7}\div \frac{5}{3}=...\) Is it a rational number?
\(\frac{-3}{8}\div \frac{-2}{9}=...\)Is it a rational number?
Can you say that rational numbers are closed under division?
We find that for any rational number a, a ÷ 0 is not defined.
So rational numbers are not closed under division.
However, if we exclude zero then the collection of, all other rational numbers is closed under division.
Commutativity Property of Rational Numbers
(i) Whole numbers Recall the commutativity of different operations for whole numbers by filling the following table.
Check whether the commutativity of the operations hold for natural numbers also.
(ii) Integers Fill in the following table and check the commutativity of different operations for integers:
(iii) Rational numbers
a.Addition You know how to add two rational numbers. Let us add a few pairs here
\(\frac{-2}{3}+\frac{5}{7}=\frac{1}{21}and\frac{5}{7}+(\frac{-2}{3})=\frac{1}{21}\)
So, \(\frac{-2}{3}+\frac{5}{7}=\frac{5}{7}+(\frac{-2}{3})\)
Also \(\frac{-6}{5}+(\frac{-8}{3})=...and\frac{-8}{3}+(\frac{-6}{5})=....\)
Is \(\frac{-6}{5}+(\frac{-8}{3})=\frac{-8}{3}+(\frac{-6}{5})?\)
Is \(\frac{-3}{8}+\frac{1}{7}=\frac{1}{7}+(\frac{-3}{8})?\)
You find that two rational numbers can be added in any order. We say that addition is commutative for rational numbers. That is, for any two rational numbers a and b, a + b = b + a.
b.Multiplication
We have, \(\frac{-7}{3}\times \frac{6}{5}=\frac{-42}{15}=\frac{6}{5}\times (\frac{-7}{3})\)
Is \(\frac{-8}{9}\times (\frac{-4}{7})=\frac{-4}{7}\times (\frac{-8}{9})?\)
Check for some more such products.
You will find that multiplication is commutative for rational numbers.
In general, a × b = b × a for any two rational numbers a and b.
c.Division
Is \(\frac{-5}{4}\div \frac{3}{7}=\frac{3}{7}\div (\frac{-5}{4})?\)
You will find that expressions on both sides are not equal.
So division is not commutative for rational numbers.
Associativity Property of Rational Numbers
(i) Whole numbers Recall the associativity of the four operations for whole numbers through this table:
Fill in this table and verify the remarks given in the last column. Check for yourself the associativity of different operations for natural numbers.
Associativity
(i) Whole numbers Recall the associativity of the four operations for whole numbers through this table:
Fill in this table and verify the remarks given in the last column.
Check for yourself the associativity of different operations for natural numbers.
(iii) Rational numbers
a.Addition
We have \(\frac{-2}{3}+[\frac{3}{5}+(\frac{-5}{6})]=\frac{-2}{3}+(\frac{-7}{30})=\frac{-27}{30}=\frac{-9}{10}\)
\([\frac{-2}{3}+\frac{3}{5}]+(\frac{-5}{6})]=\frac{-1}{15}+(\frac{-5}{6})=\frac{-27}{30}=\frac{-9}{10}\)
So, \(\frac{-2}{3}+[\frac{3}{5}+(\frac{-5}{6})]=[\frac{-2}{3}+\frac{3}{5}]+(\frac{-5}{6})\)
Find \(\frac{-1}{2}+[\frac{3}{7}+(\frac{-4}{3})]and[\frac{-1}{2}+\frac{3}{7}]+(\frac{-4}{3})\) Are the two sums equal?
Take some more rational numbers, add them as above and see if the two sums are equal. We find that addition is associative for rational numbers. That is, for any three rational numbers a, b and c, a + (b + c) = (a + b) + c.
b.Subtraction
You already know that subtraction is not associative for integers, then what about rational numbers.
Is \(\frac{-2}{3}-[\frac{-4}{5}-\frac{1}{2}]=[\frac{2}{3}-(\frac{-4}{5})]-\frac{1}{2}?\)
Check for yourself.
Subtraction is not associative for rational numbers.
c.Multiplication
Let us check the associativity for multiplication.
\(\frac{-7}{3}\times [\frac{5}{4}-\frac{2}{9}]=\frac{-7}{3}\times \frac{10}{36}=-\frac{70}{108}=\frac{-35}{54}\)
\((\frac{-7}{3}\times \frac{5}{4})\times \frac{2}{9}=...\)
We find that \(\frac{-7}{3}\times (\frac{5}{4}\times \frac{2}{9})=(\frac{-7}{3}\times \frac{5}{4})\times \frac{2}{9}\)
Is \(\frac{-2}{3}\times (\frac{-6}{7}\times \frac{4}{5})=(\frac{2}{3}\times \frac{-6}{7})\times \frac{4}{5}?\)
Take some more rational numbers and check for yourself.
We observe that multiplication is associative for rational numbers. That is for any three rational numbers a, b and c, a × (b × c) = (a × b) × c.
d.Division
Recall that division is not associative for integers, then what about rational numbers?
Let us see if \(\frac{1}{2}\div \left[ \frac{-1}{3}\div \frac{2}{5} \right]=\left[ \frac{1}{2}\div \left( \frac{-1}{3} \right) \right]\div \frac{2}{5}\)
We have, LHS = \(\frac{1}{2}\div (\frac{-1}{3}\div \frac{2}{5})=\frac{1}{2}\div (\frac{-1}{3}\times \frac{5}{2})\) (reciprocal of \(\frac{2}{5}\)is \(\frac{5}{2}\) )
= \(\frac{1}{2}\div (\frac{-5}{6})=...\)
RHS = \([\frac{1}{2}\div (\frac{-1}{3})]\div \frac{2}{5}\)
= \((\frac{1}{2}\times \frac{-3}{1})\div \frac{2}{5}\)
= \(\frac{-3}{2}\div \frac{2}{5}=...\)
Is LHS = RHS? Check for yourself. You will find that division is not associative for rational numbers.
Example 1:
Find \(\frac{3}{7}+(\frac{-6}{11})+(\frac{-8}{21})+(\frac{5}{22})\)
Solution: \(\frac{3}{7}+(\frac{-6}{11})+(\frac{-8}{21})+(\frac{5}{22})\)
=\(\frac{198}{462}+(\frac{-252}{462})+(\frac{-176}{462})+(\frac{105}{462})\) (Note that 462 is the LCM of 7, 11, 21 and 22)
= \(\frac{198-252-176+105}{462}=\frac{-125}{462}\)
We can also solve it as
\(\frac{3}{7}+(\frac{-6}{11})+(\frac{-8}{21})+\frac{5}{22}\)
\(=[\frac{3}{7}+(\frac{-8}{21})]+[\frac{-6}{11}+\frac{5}{22}]\) (by using commutativity and associativity)
\(=[\frac{9+(-8)}{21}]+[\frac{-12+5}{22}]\) (LCM of 7 and 21 is 21; LCM of 11 and 22 is 22)
= \(\frac{1}{21}+(\frac{-7}{22})=\frac{22-147}{462}=\frac{-125}{462}\)
Do you think the properties of commutativity and associativity made the calculations easier?
Example 2:
Find \(\frac{-4}{5}\times \frac{3}{7}\times \frac{15}{16}\times \left( \frac{-14}{9} \right)\)
Solution: We have
\(\frac{-4}{5}\times \frac{3}{7}\times \frac{15}{16}\times \left( \frac{-14}{9} \right)\)
\(\left( -\frac{4\times 3}{5\times 7} \right)\times \left( \frac{15\times (-14)}{16\times 9} \right)\)
= \(\frac{-12}{35}\times \left( \frac{-35}{24} \right)=\frac{-12\times (-35)}{35\times 24}=\frac{1}{2}\)
We can also do it as.
\(\frac{-4}{5}\times \frac{3}{7}\times \frac{15}{16}\times \left( \frac{-14}{9} \right)\)
=\(\left( \frac{-4}{5}\times \frac{15}{16} \right)\times \left[ \frac{3}{7}\times \left( \frac{-14}{9} \right) \right]\)(Using commutativity and associativity)
=\(\frac{-3}{4}\times \left( \frac{-2}{3} \right)=\frac{1}{2}\)
The role of zero (0)
Look at the following.
2 + 0 = 0 + 2 = 2 (Addition of 0 to a whole number)
– 5 + 0 = ... + ... = – 5 (Addition of 0 to an integer)
\(\frac{-2}{7}+...=0+\left( \frac{-2}{7} \right)=\frac{-2}{7}\) (Addition of 0 to a rational number)
You have done such additions earlier also. Do a few more such additions.
What do you observe? You will find that when you add 0 to a whole number, the sum is again that whole number. This happens for integers and rational numbers also.
In general, a + 0 = 0 + a = a, where a is a whole number
b + 0 = 0 + b = b, where b is an integer
c + 0 = 0 + c = c, where c is a rational number
Zero is called the identity for the addition of rational numbers. It is the additive identity for integers and whole numbers as well.
The role of (1)
We have,
5 × 1 = 5 = 1 × 5 (Multiplication of 1 with a whole number)
\(\begin{align} & \frac{-2}{7}\times 1=...\times ...=\frac{-2}{7} \\ & \frac{3}{8}\times ....=1\times \frac{3}{8}=\frac{3}{8} \\ \end{align}\)
What do you find?
You will find that when you multiply any rational number with 1, you get back the same rational number as the product. Check this for a few more rational numbers. You will find that, a × 1 = 1 × a = a for any rational number a.
We say that 1 is the multiplicative identity for rational numbers.
Distributivity of multiplication over addition for rational numbers
To understand this, consider the rational numbers \(\frac{-3}{4},\frac{2}{3}and\frac{-5}{6}\)
\(\frac{-3}{4}\times \left\{ \frac{2}{3}+\left( \frac{-5}{6} \right) \right\}=\frac{-3}{4}\times \left\{ \frac{(4)+(-5)}{6} \right\}\)
\(\frac{-3}{4}\times \left( \frac{-1}{6} \right)=\frac{3}{24}=\frac{1}{8}\)
Also, \(\frac{-3}{4}\times \frac{2}{3}=\frac{-3\times 2}{4\times 3}=\frac{-6}{12}=\frac{-1}{2}\)
And \(\frac{-3}{4}\times \frac{-5}{6}=\frac{5}{8}\)
Therefore, \(\left( \frac{-3}{4}\times \frac{2}{3} \right)+\left( \frac{-3}{4}\times \frac{-5}{6} \right)=\frac{-1}{2}+\frac{5}{8}=\frac{1}{8}\)
Thus, \(\frac{-3}{4}\times \left\{ \frac{2}{3}+\frac{-5}{6} \right\}=\left( \frac{-3}{4}\times \frac{2}{3} \right)+\left( \frac{-3}{4}\times \frac{-5}{6} \right)\)
Example 3: Find \(\frac{2}{5}\times \frac{-3}{7}-\frac{1}{14}-\frac{3}{7}\times \frac{3}{5}\)
Solution: \(\frac{2}{5}\times \frac{-3}{7}-\frac{1}{14}-\frac{3}{7}\times \frac{3}{5}=\frac{2}{5}\times \frac{-3}{7}-\frac{3}{7}\times \frac{3}{5}-\frac{1}{14}\) (by commutativity)
= \(\frac{2}{5}\times \frac{-3}{7}+\left( \frac{-3}{7} \right)\times \frac{3}{5}-\frac{1}{14}\)
= \(\frac{-3}{7}+\left( \frac{2}{5}+\frac{3}{5} \right)-\frac{1}{14}\) (by distributivity)
= \(\frac{-3}{7}\times 1-\frac{1}{14}=\frac{-6-1}{14}=\frac{-1}{2}\)