I'm going to work out j_random_hacker's hint. Let s, t
be a maximally distant pair. Let u
be the arbitrary vertex. We have a schematic like
u



x
/ \
/ \
/ \
s t ,
where x
is the junction of s, t, u
(i.e. the unique vertex that lies on each of the three paths between these vertices).
Suppose that v
is a vertex maximally distant from u
. If the schematic now looks like
u



x v
/ \ /
/ *
/ \
s t ,
then
d(s, t) = d(s, x) + d(x, t) <= d(s, x) + d(x, v) = d(s, v),
where the inequality holds because d(u, t) = d(u, x) + d(x, t)
and d(u, v) = d(u, x) + d(x, v)
. There is a symmetric case where v
attaches between s
and x
instead of between x
and t
.
The other case looks like
u

*v

x
/ \
/ \
/ \
s t .
Now,
d(u, s) <= d(u, v) <= d(u, x) + d(x, v)
d(u, t) <= d(u, v) <= d(u, x) + d(x, v)
d(s, t) = d(s, x) + d(x, t)
= d(u, s) + d(u, t)  2 d(u, x)
<= 2 d(x, v)
2 d(s, t) <= d(s, t) + 2 d(x, v)
= d(s, x) + d(x, v) + d(v, x) + d(x, t)
= d(v, s) + d(v, t),
so max(d(v, s), d(v, t)) >= d(s, t)
by an averaging argument, and v
belongs to a maximally distant pair.