374 Cones and conics
coordinate axes, find the equation of the line T1 tangent to the ellipse at
P1. Ins.:
XIX
a2+ UZ = 1.9 Find the coordinates of the points where the tangent T1 of Problem 8
intersects the coordinate axes. Ins.:\xl'O)' (0")
10 Find the coordinates of the points where the tangent Ti of Problem 8
intersects the lines through the foci perpendicular to the major axis. llns.:(-ae,
yl +eal)), \ae' y, \1
11 Find the coordinates of the points where the tangent Ti of Problem 8
intersects the directrices of the ellipse. Ins..:(( 11
(-e'yl\1+aee'yl\1\ ae12 Let the line T1 tangent to an ellipse at P, intersect a directrix at Q, and
let F be the focus corresponding to the directrix. With the aid of Problem 11
and the fact that b2 = a2(l - e2), prove that the line FQ, is perpendicular to the
line FP1. Remark: This result has some quite surprising consequences. If the
focus F, directrix D, and one single point Pj(xl,yl) of an ellipse are marked in a
plane, we can give a simple rule for drawing the line T which is tangent to theFigure 6.392undrawn ellipse at Pi. In case P1 is on the
line through F perpendicular to D, the
tangent T1 is the line through P1 parallel to
D. Otherwise, the tangent T1 is the line
containing P1 and the point Q, where the
line through F perpendicular to the line FP1
intersects the directrix. This result implies
that if P1 and P2 are points at the end of aP1(xi,yl'1 focal chord (a chord containing a focus), then
the tangents at P1 and P2 intersect at the point
Q, on the directrix where the line through the
focus perpendicular to the line P1P2 meets the
directrix. Figure 6.392, in which a part of
the ellipse is drawn, illustrates this elegant
geometric fact.
13 Figure 6.392 illustrates another in-
teresting geometric fact. Then line OP1
and the line through F perpendicular to the tangent Ti at P1 intersect ata point
11 on the directrix. Prove the fact by proving that each line intersects the direc-
trix at the point I (ae, ayex1)i.