Pair of Linear Equations In Two Variables

3.1 Introduction

You must have come across situations like the one given below :

Akhila went to a fair in her village. She wanted to enjoy rides on the Giant Wheel and play Hoopla (a game in which you throw a ring on the items kept in a stall, and if the ring covers any object completely, you get it). The number of times she played Hoopla is half the number of rides she had on the Giant Wheel. If each ride costs ₹ 3 , and a game of Hoopla costs ₹ 4, how would you find out the number of rides she had and how many times she played Hoopla, provided she spent ₹ 20.

May be you will try it by considering different cases. If she has one ride, is it possible? Is it possible to have two rides? And so on. Or you may use the knowledge of Class IX, to represent such situations as linear equations in two variables.

Let us try this approach.

Denote the number of rides that Akhila had by $x$, and the number of times she played Hoopla by $y$. Now the situation can be represented by the two equations:

$$ \begin{aligned} y & =\frac{1}{2} x \tag{1} \\ \end{aligned} $$

$$ \begin{aligned} 3 x+4 y & =20 \tag{2} \end{aligned} $$

Can we find the solutions of this pair of equations? There are several ways of finding these, which we will study in this chapter.

3.2 Graphical Method of Solution of a Pair of Linear Equations

A pair of linear equations which has no solution, is called an inconsistent pair of linear equations. A pair of linear equations in two variables, which has a solution, is called a consistent pair of linear equations. A pair of linear equations which are equivalent has infinitely many distinct common solutions. Such a pair is called a dependent pair of linear equations in two variables. Note that a dependent pair of linear equations is always consistent.

We can now summarise the behaviour of lines representing a pair of linear equations in two variables and the existence of solutions as follows:

(i) the lines may intersect in a single point. In this case, the pair of equations has a unique solution (consistent pair of equations).

(ii) the lines may be parallel. In this case, the equations have no solution (inconsistent pair of equations).

(iii) the lines may be coincident. In this case, the equations have infinitely many solutions [dependent (consistent) pair of equations].

Consider the following three pairs of equations.

(i) $x-2 y=0$ and $3 x+4 y-20=0 \quad$ (The lines intersect)

(ii) $2 x+3 y-9=0$ and $4 x+6 y-18=0 \quad$ (The lines coincide)

(iii) $x+2 y-4=0$ and $2 x+4 y-12=0 \quad$ (The lines are parallel)

Let us now write down, and compare, the values of $\frac{a_1}{a_2}, \frac{b_1}{b_2}$ and $\frac{c_1}{c_2}$ in all the three examples. Here, $a_1, b_1, c_1$ and $a_2, b_2, c_2$ denote the coefficents of equations given in the general form in Section 3.2.

Table 3.1

Sl No. Pair of lines $\frac{a_1}{a_2}$ $\frac{b_1}{b_2}$ $\frac{c_1}{c_2}$ Compare the ratios Graphical representation Algebraic interpretation
1. $x-2 y=0$ $3 x+4 y-20=0$ $\frac{1}{3}$ $\frac{-2}{4}$ $\frac{0}{-20}$ $\frac{a_1}{a_2} \neq \frac{b_1}{b_2}$ Intersecting lines Exactly one solution (unique)
2. $2 x+3 y-9=0$ $4 x+6 y-18=0$ $\frac{2}{4}$ $\frac{3}{6}$ $\frac{-9}{-18}$ $\frac{a_1}{a_2}=\frac{b_1}{b_2}=\frac{c_1}{c_2}$ Coincident lines Infinitely many solutions
3. $2 y-4=0$ $\frac{1}{2}$ $\frac{2}{4}$ $\frac{-4}{-12}$ $\frac{a_1}{a_2}=\frac{b_1}{b_2} \neq \frac{c_1}{c_2}$ Parallel lines No solution

From the table above, you can observe that if the lines represented by the equation

$ a_1 x+b_1 y+c_1=0 $

and

$ a_2 x+b_2 y+c_2=0 $

are

(i) intersecting, then $\frac{a_1}{a_2} \neq \frac{b_1}{b_2}$.

(ii) coincident, then $\frac{a_1}{a_2}=\frac{b_1}{b_2}=\frac{c_1}{c_2}$.

(iii) parallel, then $\frac{a_1}{a_2}=\frac{b_1}{b_2} \neq \frac{c_1}{c_2}$.

In fact, the converse is also true for any pair of lines. You can verify them by considering some more examples by yourself.

3.3 Algebraic Methods of Solving a Pair of Linear Equations

In the previous section, we discussed how to solve a pair of linear equations graphically. The graphical method is not convenient in cases when the point representing the solution of the linear equations has non-integral coordinates like $(\sqrt{3}, 2 \sqrt{7})$, $(-1.75,3.3),(\frac{4}{13}, \frac{1}{19})$, etc. There is every possibility of making mistakes while reading such coordinates. Is there any alternative method of finding the solution? There are several algebraic methods, which we shall now discuss.

3.3.1 Substitution Method:

We shall explain the method of substitution by taking some examples.

Verification : Substituting $x=\frac{49}{29}$ and $y=\frac{19}{29}$, you can verify that both the Equations (1) and (2) are satisfied.

To understand the substitution method more clearly, let us consider it stepwise:

Step 1 : Find the value of one variable, say $y$ in terms of the other variable, i.e., $x$ from either equation, whichever is convenient.

Step 2 : Substitute this value of $y$ in the other equation, and reduce it to an equation in one variable, i.e., in terms of $x$, which can be solved. Sometimes, as in Examples 9 and 10 below, you can get statements with no variable. If this statement is true, you can conclude that the pair of linear equations has infinitely many solutions. If the statement is false, then the pair of linear equations is inconsistent.

Step 3 : Substitute the value of $x$ (or $y$ ) obtained in Step 2 in the equation used in Step 1 to obtain the value of the other variable.

Remark : We have substituted the value of one variable by expressing it in terms of the other variable to solve the pair of linear equations. That is why the method is known as the substitution method.

3.3.2 Elimination Method

Now let us consider another method of eliminating (i.e., removing) one variable. This is sometimes more convenient than the substitution method. Let us see how this method works.

Remarks :

1. The method used in solving the example above is called the elimination method, because we eliminate one variable first, to get a linear equation in one variable.

In the example above, we eliminated $y$. We could also have eliminated $x$. Try doing it that way.

2. You could also have used the substitution, or graphical method, to solve this problem. Try doing so, and see which method is more convenient.

Let us now note down these steps in the elimination method :

Step 1 : First multiply both the equations by some suitable non-zero constants to make the coefficients of one variable (either $x$ or $y$ ) numerically equal.

Step 2 : Then add or subtract one equation from the other so that one variable gets eliminated. If you get an equation in one variable, go to Step 3.

If in Step 2, we obtain a true statement involving no variable, then the original pair of equations has infinitely many solutions.

If in Step 2, we obtain a false statement involving no variable, then the original pair of equations has no solution, i.e., it is inconsistent.

Step 3 : Solve the equation in one variable ( $x$ or $y$ ) so obtained to get its value.

Step 4 : Substitute this value of $x$ (or $y$ ) in either of the original equations to get the value of the other variable.

Now to illustrate it, we shall solve few more examples.

3.4 Summary

In this chapter, you have studied the following points:

1. A pair of linear equations in two variables can be represented, and solved, by the:

(i) graphical method

(ii) algebraic method

2. Graphical Method :

The graph of a pair of linear equations in two variables is represented by two lines.

(i) If the lines intersect at a point, then that point gives the unique solution of the two equations. In this case, the pair of equations is consistent.

(ii) If the lines coincide, then there are infinitely many solutions - each point on the line being a solution. In this case, the pair of equations is dependent (consistent).

(iii) If the lines are parallel, then the pair of equations has no solution. In this case, the pair of equations is inconsistent.

3. Algebraic Methods : We have discussed the following methods for finding the solution(s) of a pair of linear equations :

(i) Substitution Method

(ii) Elimination Method

4. If a pair of linear equations is given by $a_1 x+b_1 y+c_1=0$ and $a_2 x+b_2 y+c_2=0$, then the following situations can arise :

(i) $\frac{a_1}{a_2} \neq \frac{b_1}{b_1}$ : In this case, the pair of linear equations is consistent.

(ii) $\frac{a_1}{a_2}=\frac{b_1}{b_2} \neq \frac{c_1}{c_2}$ : In this case, the pair of linear equations is inconsistent.

(iii) $\frac{a_1}{a_2}=\frac{b_1}{b_2}=\frac{c_1}{c_2}$ : In this case, the pair of linear equations is dependent and consistent.

5. There are several situations which can be mathematically represented by two equations that are not linear to start with. But we alter them so that they are reduced to a pair of linear equations.



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