ON EVOLUTES AND PARALLEL CURVES.
43
[493
493]
together with
’ 2 respectively;
des m - f— 2g
; but here I
point on the
F each of the
\-g), =n-g
i. Hence also
g, we have a
IJ; and thus
nches at each
>n the parallel
4-2 n — 2f — 2 g
which relation
hat n' —f — g'
id remarkable.
n" = m, i" = n,
:' = 2*, /' = 2/
e here breaks
g, but where
n'-f'-g' = 0;
ion, break up
set.
n'-f'-g' = 0,
ed quantity ©)
are m — к, n — m, t — n — ©, к — n' — 3m' 4 3к — ©, or substituting for m',
their values, and comparing with the formulae in regard to the evolute, we have
n', К
m" = 2a - 6/ - 6g, = 2m",
n'" = 2m 4- 2n -2f— 2g, = 2n",
t" = 2n - ©, = 2i" + 2 (n -f-g)- ©,
k" = -6m- 4n + 6a - 12/- \2g - ©, = 2k" + 2(n-f-g) - ©,
where m", n", i", k" refer to the evolute. Hence by assuming © = 2 (n -f- g), the
values of m'", n'", c", k" become 2m", 2n", 2i", 2k", viz. the evolute of the parallel
curve is the evolute of the original curve taken twice. Observe that in the foregoing
value of ©, the letters n, f g refer not to the parallel curve, the evolute whereof is
under consideration, but to the curve from which such parallel curve was derived;
this value © = 2 (n —f— g) is not a value of © applicable to be substituted in the
evolute-formuke for the case of a curve which has with its evolute a (1, 2) corre
spondence.
Instead of the foregoing case of the f viz. /- and ^-singularities, we may, as
regards the parallel curve, consider the original curve as having any I- and /-singu
larities whatever. Suppose in this case (excluding always the line IJ and the tangents
at I or /) the number of tangents from I to the curve is =n— I, and the number
of tangents from J to the curve is =n — J, then when the radius of the variable
curve is = 0, the parallel curve becomes the original curve twice together with the
(n — I) + (w — J), =27i — I — J tangents ; so that the order is m = 2m 4- 2w — I — JQ) ; we
have, as before, n = 2n and i = 2t, and these values give k , so that the equations are
m' = 2m + 2n — I — J,
n = 2 n,
l = — 6m 4- 2a, = 21,
k = 2 cl — I — J, = 6n + 2k — 3I — 3/.
Suppose 2n—I — J=0\ this implies n — I= 0, n — J= 0 since neither n — I nor
!/ — J can be negative; viz. that there are no /- or /-tangents; and conversely, when
his is the case 2n — I — J= 0: and we have then m, n, i, k = 2m, 2n, 2o, 2k ; viz.
t is assumed, as before, that the parallel curve breaks up into two distinct curves
uch as the original curve; that is, the condition in order that the parallel curve
hould break up, is that the original curve has no focal tangents. Observe that the
lumber of foci is =(n — I)(n — J) which is =0 if only n — I— 0 or n — J= 0; but as
egards real curves /=/, so that the equations n — I= 0 and n — J=0 aie one and
he same equation, satisfied if (n — I) (n — J) = 0; so that for a real curve without foci
real or imaginary) the parallel curve will break up. An instance given to me b\
)r Salmon is the curve ^ + ^-c S = 0 or + 27c*V = 0, here m = 6, n = 4,
1 That the order of the evolute is not (in every case of a curve with singularities) one-half this, or
=m+n-^ (I+J), is at once seen by remarking that there is no reason why I+J sliou e even.
6—2
