so
c=^32
and the equation isy=^12 ( 3 −x)orx+ 2 y− 3 =0.
7.2.6 Intersecting lines
➤
205 222➤
If two lines intersect, then their point of intersection must satisfy both of their equations.
Thus, if the lines are:
ax+by=c
dx+ey=f
then at the point of intersection these equations must be satisfied simultaneously (48
➤
).
Although one would find this intersection point by solving these equations, the geomet-
rical picture provides a nice visual means of discussing the different possibilities for the
solution of the equations. Thus, we find the following cases, with some examples you can
check:
- if the lines are not parallel (i.e. do not have the same gradient) then they
will intersect at some point – i.e. the equations will have a solution.
Example
x+ 2 y= 1
x−y= 0
have different gradients and intersect at
( 1
3 ,
1
3
)
.
- If the lines are parallel (same gradient) then they will never intersect
and there will be no solution to the equations.
Example
2 x+y= 0
4 x+ 2 y= 3
These are parallel, but through different points – the first passes through
the origin, the second through
(
0 ,^32
)
. These lines will never intersect
and so the equations have no solution.
- If the lines areidentical, i.e. coincide (same gradients, same intercepts),
then they intersect at every point on the line(s) – the equations have an
infinite number of solutions.
Example
x+ 3 y= 1
2 x+ 6 y= 2