7.8 USING VECTORS TO FIND DISTANCES
of the sphere. This is easily expressed in vector notation as
|r−c|^2 =(r−c)·(r−c)=a^2 , (7.43)
wherecis the position vector of the centre of the sphere andais its radius.
Find the radiusρof the circle that is the intersection of the planenˆ·r=pand the sphere
of radiusacentred on the point with position vectorc.
The equation of the sphere is
|r−c|^2 =a^2 , (7.44)
and that of the circle of intersection is
|r−b|^2 =ρ^2 , (7.45)
whereris restricted to lie in the plane andbis the position of the circle’s centre.
Asblies on the plane whose normal isnˆ,thevectorb−cmust be parallel toˆn,i.e.
b−c=λnˆfor someλ. Further, by Pythagoras, we must haveρ^2 +|b−c|^2 =a^2. Thus
λ^2 =a^2 −ρ^2.
Writingb=c+
√
a^2 −ρ^2 ˆnand substituting in (7.45) gives
r^2 − 2 r·
(
c+
√
a^2 −ρ^2 nˆ
)
+c^2 +2(c·nˆ)
√
a^2 −ρ^2 +a^2 −ρ^2 =ρ^2 ,
whilst, on expansion, (7.44) becomes
r^2 − 2 r·c+c^2 =a^2.
Subtracting these last two equations, usingnˆ·r=pand simplifying yields
p−c·nˆ=
√
a^2 −ρ^2.
On rearrangement, this givesρas
√
a^2 −(p−c·nˆ)^2 , which places obvious geometrical
constraints on the valuesa,c,nˆandpcan take if a real intersection between the sphere
and the plane is to occur.
7.8 Using vectors to find distances
This section deals with the practical application of vectors to finding distances.
Some of these problems are extremely cumbersome in component form, but they
all reduce to neat solutions when general vectors, with no explicit basis set,
are used. These examples show the power of vectors in simplifying geometrical
problems.
7.8.1 Distance from a point to a line
Figure 7.14 shows a line having directionbthat passes through a pointAwhose
position vector isa. To find theminimum distancedof the line from a pointP
whose position vector isp, we must solve the right-angled triangle shown. We see
thatd=|p−a|sinθ; so, from the definition of the vector product, it follows that
d=|(p−a)×bˆ|.