250
ON THE SEXTACTIC POINTS OF A PLANE CURVE.
[341
and substituting the values
TU=2<P, Vtf=—— tf, BU=SH,
to — 1
we find the before-mentioned expression of di 2 U.
60. Operating with the two sides of the same equation on a function H of the
order to', we find
to (in — 1) UrH — (in — l) 2 d' 2 H = m (in' — 1) A>H
-2 (m'-l)$V£T
+ &0&;
and in particular if H is the Hessian, then writing m! = 3to — 6, and putting U = 0,
we find the before-mentioned expression for d 2 H.
61. But we may also from the general identical equation deduce the expression
for (3Hf. In fact taking H a function of the degree in' and writing
( a , fi, y) = (d x H, d y H, 3 Z H),
we have
m (in — 1) U (a, .. h)/xd z H — vd y H, vd x H — Xd z H, Xd y H — fid x H) 2 — (in — l) 2 (3H) 2
= m'^H 2 - 2m'^HV H + ^ 2 (21, .. $3 X H, 3 y H, d z Hf;
and if H be the Hessian, then writing in' = 3in — 6 and putting also 17= 0, we find
the before-mentioned expression for (3H) 2 .
62. Proof of equation
^ = “ i (*&* + tfiv + Z dz) + —“i V •
We have
3 2 = 3.3 = {(Bv — C/ji) d x + (C f A. — Av) d y + (Afi — BX) d z }.
(\(Cd y — Bd z ) +fi(Ad z — Cd x ) + v(Bd x — Ady)),
which is
= A (C'dy - B’d z ) + ya (A'd z - G'd x ) + v (B'd x - A'dy),
where
A' = dA — a (Bv — C/x) + h (GX — A v) + g (A ya — BX)
= X (hG — gB) + /J, (gA — aC) + v (aB — hA ),
with the like values for B’ and G'. Substituting the values
(to — 1) (A, B, G) = (ax + liy + gz, hx + bg + fz, gx +fy + cz),
we have
(to — 1) A' = X (®g - fiz) + ya (% -23z) + v ((% - %z);
and similarly
(to — 1) B' = X (2\z — ®x) + ^ (fiz — %x) + v (®z — (£x),
(in - 1) G' = X (fix - 21y) + fi (23a? - fig) + v ($x - ®y),
