48 ON THE CONICS WHICH PASS THROUGH TWO GIVEN POINTS [392
The equation of the chord of contact is
x + y V (ran) + yz = 0,
which for 7=1 is parallel to y — 0 and for 7 = V (ran) is parallel to x — 0. But the
coordinates of the centre are
x : y : 2 = — 7 + V (mn) : - 7 + 1 : V (mn) + 1 + - 1 - {V (m) - V (n)} 2 ,
which for 7=1 give
y = 0, x : 2 = — 1+V (mn) : V (mn) + 1 + \ {V (m) — V (n)} 2 , = — 2 + 2 ^ (mn) : 2 + m + n,
and for 7 = V (mn) give
x = 0,
I 7Y) -1- 11
y : 2 = 1 - V (mn) : V (mn) + 1 + ^ W ( m ) ~ V ( w )} 2 , = 2 ~ 2 \/(mn) : 2 \/(wn) + •
The line drawn from the fixed point on the chord of contact to the centre has for
its equation
x + y V (ran) + y z = 0,
where, writing for a?, y, z the coordinates of the centre, we have
- 7 {1 + V (ran)} + 2 \/ (ran) + 7'
V (mn) + 1 + ^ (V (w) - V (n)} 2
= 0,
that is
, _ 7 11 + V (mn)} — 2 V (mn)
7 =
1 + V (ran) + ^ (V (ra) - V (n)} 2
or, what is the same thing,
7 7 {V (ra) - V (n)} 2 + 27 {1 + V (ran)} ’
2 7
- 7 IV (ra) + V (n)}
and consequently y = 7 only for 7 = 0.
It is now easy to trace the corresponding positions of the chord of contact through
the fixed point [x + y V (ran) = 0, z = 0}, and of the centre on the hyperbola which is
the curve of centres: see fig. 2 in the plate facing p. 52.
The lines 0P. 2 , OL, 0©, 0P 1} OX, OG, OH are positions of the chord of contact,
and the points P«, L, ©, P 1} X, G, H, on the hyperbola which is the curve of centres
are the corresponding positions of the centre.
