From the first equation, write y in terms of x
y = 2 – 2x …….(i)
Substitute different values of x in (i) to get different values of y
For x = 0, y = 2 – 0 = 2
For x = 1, y = 2 – 2 = 0
For x = 2, y = 2 – 4 = -2
Thus, the table for the first equation (2x + y = 2) is
Now, plot the points A(0, 2), B(1, 0) and C(2, -2) on a graph paper and join A, B and C to get the graph of 2x + y = 2.
From the second equation, write y in terms of x
y = 6 – 2x …….(ii)
Now, substitute different values of x in (ii) to get different values of y
For x = 0, y = 6 – 0 = 6
For x = 1, y = 6 – 2 = 4
For x = 3, y = 6 – 6 = 0
So, the table for the second equation (2x + y = 6) is
Now, plot the points D(0,6), E(1, 4) and F(3,0) on the same graph paper and join D, E and F to get the graph of 2x + y = 6.
From the graph, it is clear that, the given lines do not intersect at all when produced. So, these lines are parallel to each other and therefore, the quadrilateral DABF is a trapezium.
The vertices of the required trapezium are D(0, 6), A (0, 2), B(1, 0) and F(3, 0).
Now,
Area(Trapezium DABF) = Area (∆DOF) – Area(∆AOB)
= \(\frac{1}2\) × 3 × 6 - \(\frac{1}2\) × 1 × 2
= 9 – 1
= 8 sq. units
Hence, the area of the required trapezium is 8 sq. units.
