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Question
Show that the lines `(x - 1)/2 = (y - 2)/3 = (z - 3)/4` and `(x - 4)/5 = (y - 1)/2` = z intersect. Also, find their point of intersection.
Solution
The given equations are `(x - 1)/2 = (y - 2)/3 = (z - 3)/4` and `(x - 4)/5 = (y - 1)/2` = z
Let `(x - 1)/2 = (y - 2)/3 = (z - 3)/4 = lambda`
∴ x = 2λ + 1, y = 3λ + 2 and z = 4λ + 3
And `(x - 4)/5 = (y - 1)/2 = z/1 = mu`
∴ x = `5mu + 4, y = 2mu + 1` and z = `mu`
If the two lines intersect each other at one point,
Then `2lambda + 1 = 5mu + 4`
⇒ `2lambda - 5mu` = 3 .....(i)
`3lambda + 2 = 2mu + 1`
⇒ `3lambda - 2mu = -1` ......(ii)
And `4lambda + 3 = mu`
⇒ `4lambda - mu = - 3` ......(iii)
Solving equations (i) and (ii) we get
`2lambda - 5mu` = 3 .......[Multiply by 3]
`3lambda - 2mu` = – 1 .......[Multiply by 2]
⇒ `6lambda - 15mu` = 9
`6lambda - 14mu` = – 2
(–) (+) (+)
`-11,u` = 11
∴ `mu = -1`
Putting the value of m in equation (i) we get,
2λ – 5(– 1) = 3
⇒ 2λ + 5 = 3
⇒ 2λ = – 2
∴ λ = – 1
Now putting the value of λ and m in equation (iii) then
4(– 1) – (– 1) = – 3
– 4 + 1 = – 3
– 3 = – 3 ....(Satisfied)
∴ Coordinates of the point of intersection are
x = 5 (– 1) + 4 = – 5 + 4 = – 1
y = 2(– 1) + 1 = – 2 + 1 = –
z = – 1
Hence, the given lines intersect each other at (– 1, – 1, – 1).
Alternately: If two lines intersect each other at a point, then the shortest distance between them is equal to 0.
For this we will use SD = `((vec"a"_2 - vec"a"_1)(vec"b"_1 xx vec"b"_2))/|vec"b"_1 xx vec"b"_2|` = 0.
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