200
ON SKEW SURFACES, OTHERWISE SCROLLS.
[339
be understood a plane passing through a tangent line of the curve. The intersection
of two consecutive tangent planes is a line meeting the two curves, which line is
the generating line of the Torse, and such Torse is therefore the Torse (m, n) in
question.
The foregoing investigation is not very satisfactory, but I confirm it by considering
the case of two plane curves, orders m and n, and classes ¡x and v, respectively. The
tangents of the two curves can, it is clear, only meet on the line of intersection of
the planes of the curves; and the construction of the Torse is in fact as follows:
from any point of the line of intersection draw a tangent to m and a tangent to n,
then the line joining the points of contact of these tangents is a generating line of
the Torse. The order of the Torse is equal to the number of generating lines which
meet an arbitrary line; and taking for the arbitrary line the line of intersection of
the two planes, it is easy to see that the only generating lines which meet the line
of intersection are those for which one of the points of contact lies on the line of
intersection; that is, they are the generating lines derived from the points in which
the line of intersection meets one or other of the two curves; they are therefore in
fact the tangents drawn to the curve n from the points in which the line of inter
section meets the curve m, together with the tangents drawn to the curve m from the
points in which the line of intersection meets the curve n. Now the line meets the
curve n in n points, and from each of these there are /a tangents to the curve m;
and it meets the curve m in m points, and from each of these there are v tangents
to the curve n; hence the entire number of the tangents in question is = n\x + mv,
which confirms the theorem.
Annex No. 5.—Order of Torse (m 2 ) (referred to, Art. 46).
We have here to find the order of the developable or Torse generated by a line
meeting a curve of the order m twice, viz., the class of the curve being /a, it is to
be shown that we have
Torse (m 2 ) = (m — 3)/x.
I deduce the expression from the formula given p. 424 of Dr Salmon’s ‘ Geometry of
Three Dimensions; ’ viz. putting in his formula /3 = 0, and /a for his r, we have
Order = 4) — | a = m/A — (4m + 4a),
where (see p. 234 et seq.)
and thence
so that we have
fx = m(m — 1) — 2 h,
= (n — m) = 3 m (m — 2) — 6h — m,
3/a — ^a = 4m, or 4m + \ a. = 3/a,
Order = (m — 3) /¿.
A more complete discussion of the Torses (m, n) and (m 2 ) is obviously desirable; but
as they are only incidentally connected with the subject of the present memoir, I have
contented myself with obtaining the required results in the way which most readily
presented itself.
