P, Q and R are any three points. The circle C on QR as diameter meets PQ in Q' and PR in R'. Show that the circle PQ'R' is orthogonal to C, and that its diameter through P is perpendicular to QR.
Prove Pascal's theorem that, if A, B, C, D, E, F are six points of a conic, the three points (AB, DE), (BC, EF) and (CD, FA) are collinear. Obtain another theorem by allowing A to coincide with B, and D with E. Deduce that, if A, B, C and D are four points on a conic, the quadrilateral formed by the tangents at A, B, C and D has the same diagonal triangle as the quadrangle ABCD.
A conic S touches the sides of a triangle ABC in D, E and F. If P is any point on EF, prove that PB and PC are conjugate with respect to S.
S is a given conic and A, B are two fixed points not lying on S. P is a variable point on S, PA meets S again in Q, and QB meets S again in R. Show that the pairs P, R belong to an involution on S if, and only if, A and B are conjugate with respect to S. Prove also that, if ABC is a self-polar triangle with respect to S, there is an infinite number of triangles LMN inscribed in S whose sides MN, NL, LM pass through A, B, C respectively.
P, Q and R are corresponding points of homographic ranges on three lines p, q and r which do not lie in a plane.
Show that the circles with respect to which a fixed line \[ ax+by+c=0 \] is the polar of the origin form a coaxal system, and find the line of centres, the radical axis, and the limiting points.
P and Q are the intersections of the line \[ lx+my+n=0 \] with the parabola \[ y^2-x=0. \] The circle on PQ as diameter meets the parabola again in R and S. Find the equation of the line RS.
Find the condition that the line \[ lx+my+n=0 \] should touch the conic \[ S_\lambda \equiv ax^2 + by^2 + c + \lambda(px+qy+r)^2 = 0. \] Show that if \[ \lambda\left(\frac{p^2}{a} + \frac{q^2}{b} + \frac{r^2}{c}\right) + 2 = 0, \] the polar reciprocal of \(S_\lambda\) with respect to the conic \[ S \equiv ax^2 + by^2 + c = 0 \] is the conic \(S_\lambda\) itself, and that the polar reciprocal of \(S\) with respect to \(S_\lambda\) is the conic \(S\) itself.
XYZ is the triangle of reference and H, K are the points \((x_1, y_1, z_1)\), \((x_2, y_2, z_2)\). The line HK meets YZ, ZX, XY in P, Q, R respectively, and the harmonic conjugates of these points with respect to H and K are P', Q', R' respectively. Find the coordinates of P', Q', R' and show that XP', YQ', ZR' are concurrent.
Show that the eight points of contact of the common tangents of the conics \begin{align*} ax^2 + by^2 + cz^2 &= 0, \\ a'x^2 + b'y^2 + c'z^2 &= 0, \end{align*} lie on a conic, and find its equation.