ON THE THEORY OF ALGEBRAIC CURVES.
50
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being coincident in the two curves, the number of points of intersection is mn — r — s ;
but the converse of this theorem is not true.
In a former paper, On the Intersection of Curves, [5], I investigated the number
of arbitrary constants in the equation of a curve of a given order p subjected to pass
through the mn points of intersection of two curves of the orders m and n respectively.
The reasoning there employed is not applicable to the case where the two curves
intersect in a number of points less than mn. Iu fact, it was assumed that, W = 0
being the equation of the required curve, W was of the form uU+vV; u, v being
polynomials of the degrees p - m, p — n respectively. This is, in point of fact, true in
the case there considered, viz. that in which the two curves intersect in mn points;
but where the number of points of intersection is less than this, u, v may be assumed
polynomials of an order higher than p — m, p — n, and yet uU+vV reduce itself to
the order p. The preceding investigations enable us to resolve the question for every
possible case.
Considering then the functions U, V determined as before by the equations (3), (4),
suppose, in the first place, we have a system of equations
a = A, /3 = B 0 — H (t equations) (8).
Assume P = (y — ax — ...) (y — /3# (y — Ox — ...),
Q =(y-Ax- ...) (y -Bx (y -Hx- ...);
T = (y-i.x-...) ... (y-KX - ...),
y =(y-\x-...) ... (y-Kx-...) ;
whence U = PT, V = QV.
Suppose T = PT + AT, T = PT + AT,
PT. U - PT . V= JAY . PT - PT. QV,
= P'T . P (PT + AT) - PT. Q (E'V + A'P),
= PT.P¥.(P- Q)+ E'V .P. AT-PT.Q. A'T,
= P {PT . E'V . (P - Q) + E'V. PAT - PT . Q. A'P},
= II suppose.
In this expression PT, E'V are of the degrees m — t, n — t, AT, AT' of the degree
- 1, and P, Q, P — Q of the degrees t, t, t- 1 respectively. The terms of II are
therefore of the degrees m + n — t — 1, m — 1, n — 1 respectively, and the largest of
these is in general m + n — t — 1. Suppose, however, that m+n — t — 1 is equal to
rn — 1 (it cannot be inferior to it), then t = n; V becomes equal to unity, or AT
vanishes. The remaining two terms of II are PT (P — Q), PAT, which are of the
degrees m- 1, n - 1 respectively. II is still of the degree m — 1, supposing m> n.
If m = n, the term PAT vanishes. II is still of the degree m — 1. Hence in every
case the degree of n is m + n — t— 1: assuming always that P — Q does not reduce
itself to a degree lower than t- 1, (which is always the' case as long as the equations
