506]
147
506.
ON THE MECHANICAL DESCRIPTION OF A CUBIC CURVE.
[From the Proceedings of the London Mathematical Society, vol. iv. (1871—1873),
pp. 175—178. Read November 14, 1872.]
If the coordinates x, y of a point on a curve are rational functions of sin cos</>,
vr — k 2 sin 2 <£, the curve has the deficiency 1, and conversely in any curve of deficiency 1
the coordinates x, y can be thus expressed in terms of the parameter </>. Hence
writing sin 0 — k sin </>, the coordinates will be rational functions of sin </>, cos cf>, cos 6,
or say of sin (f), cos cf), sin 0, cos 0; and for the mechanical representation of the relation
k sin cf) — sin 0, we require only a rod 0A rotating about the fixed point 0, and con
nected with it by a pin at A, a rod AB, the other extremity of which, B, moves in
a fixed line Ox. The curve most readily obtained by such an arrangement is that
described by a point G rigidly connected with the rod AB; this is however a quartic
curve (with two dps., since its deficiency is =1). I first considered the cubic curve
xy —1 — V(1 — x 2 ) (1 — k 2 x 2 ),
or say
xy — 1 = — V(1 — x 2 ) (1 — k 2 x 2 );
writing herein x = sin <£, and as before k sin 0 = sin 0, we have then y sin <£ = 1 — cos 0 cos <f>;
which values may be written
X = Sin (f),
y =
1 — cos (0 + <f>)
sin (f)
sin 0.
I found, however, that this was not the cubic curve most easily constructed; and I
ultimately devised a mechanical arrangement consisting of
1. Rod OH, and connected with it by a pin at H, rod HI (*).
1 There was a mechanical convenience in this, but observe that producing OH to meet IP in T, the
single straight rod OHT might have been made use of.
19—2
