Problems

Complex numbers \(z_r (z_r = x_r+iy_r)\) are represented in the Argand diagram by points \(P_r\) with co-ordinates \((x_r, y_r)\). Prove that

1. [(i)] a necessary and sufficient condition for the points \(P_1, P_2, P_3, P_4\) to be concyclic is that \[ \frac{(z_1-z_2)(z_3-z_4)}{(z_1-z_4)(z_3-z_2)} \] should be real;
2. [(ii)] a necessary and sufficient condition for the triangles \(P_1P_2P_3\) and \(P_4P_5P_6\) to be similar and with the same orientation is \[ \begin{vmatrix} z_1 & z_2 & z_3 \\ z_4 & z_5 & z_6 \\ 1 & 1 & 1 \end{vmatrix} = 0. \]

A match between two players \(A\) and \(B\) is won by whoever first wins \(n\) games. \(A\)'s chances of winning, drawing or losing any particular game are \(p, q\) and \(r\) respectively. Prove that his chance of winning the match is \(p^2(p+3r)/(p+r)^3\) if \(n\) is 2, and \[ p^3(p^2+5pr+10r^2)/(p+r)^5 \] if \(n\) is 3.

The lines joining a point \(P\) to the vertices of a triangle \(ABC\) meet the opposite sides in \(L, M, N\). A variable conic through \(L, M, N, P\) meets \(BC\) again in \(U\), and the tangent to the conic at \(P\) meets \(BC\) in \(V\). Prove that \(U, V\) are harmonic conjugates with respect to \(B, C\). \newline A line \(p\) through \(P\) meets \(BC, CA, AB\) in \(A', B', C'\), and \(L'\) is the harmonic conjugate of \(A'\) with respect to \(B\) and \(C\); \(M', N'\) are similarly defined. Prove that \(L, M, N, L', M', N'\) lie on a conic which touches \(p\) at \(P\).

Prove that, if \(f(x)\) is a function of \(x\) which has a derivative \(f'(x)\) for all values of \(x\) between \(a\) and \(b\) inclusive, and if \(f(a)=f(b)\), there is at least one value \(\xi\) between \(a\) and \(b\) for which \(f'(\xi)=0\). \newline Deduce from this theorem that, for some \(\xi\) between \(a\) and \(b\), \[ \text{(i)} \quad \frac{\phi(b)-\phi(a)}{\psi(b)-\psi(a)} = \frac{\phi'(\xi)}{\psi'(\xi)}, \] and that, for another \(\xi\), \[ \text{(ii)} \quad \frac{\phi(\xi)-\phi(a)}{\psi(b)-\psi(\xi)} = \frac{\phi'(\xi)}{\psi'(\xi)}, \] where in each case it is assumed that \(\phi'(x), \psi'(x)\) exist for all values of \(x\) between \(a\) and \(b\) inclusive, and that \(\psi'(x)\) does not vanish for any \(x\) between \(a\) and \(b\).

The framework \(ABCDEFGH\) consists of eight equal uniform heavy rods smoothly jointed at their ends, and is maintained in the shape of a regular octagon by light struts \(AF, AG, BD\) and \(BE\). The framework is in equilibrium, suspended from the mid-point of \(AB\). State which (if any) of the stresses in the struts are thrusts and which tensions, and determine the ratio of the magnitudes of the stresses in \(AF\) and \(AG\).

A uniform chain of weight \(w\) per unit length hangs in equilibrium under gravity over a rough circular cylinder of radius \(a\). The chain, the length of which exceeds \(\pi a\), lies in a plane perpendicular to the horizontal axis of the cylinder with one end \(A\) on the same level as the axis, and \(T\) is the tension in the chain at the point at an angular distance \(\theta\) (less than \(\pi\)) from \(A\). If the chain is on the point of slipping in the direction in which \(\theta\) increases, prove that \[ \frac{d}{d\theta}(Te^{-\mu\theta}) = wa(\cos\theta+\mu\sin\theta)e^{-\mu\theta}, \] where \(\mu\) is the coefficient of friction, and hence find the length of the part of the chain not in contact with the cylinder.

A solid body of uniform density consists of a circular cone of perpendicular height \(4a\), to whose base (which is a circle of radius \(a\)) is attached a hemisphere of radius \(a\), the plane surface of the hemisphere coinciding with the base of the cone. The body is free to rotate about a fixed horizontal axis through the vertex of the cone. Find the length of the simple pendulum having the same period for small oscillations.

Two equal balls \(A, B\) are placed on the baulk line \(PQ\) of a billiard table, which may be regarded as a perfectly rough horizontal plane \(JKLM\) of rectangular shape. \(PQ\) is parallel to the side \(JK\) and is distant \(5l\) from it, \(P\) being a point of the side \(JM\). \(A\) is equidistant from \(P\) and from \(B\), and \(PB=2l\). The balls are struck simultaneously, \(A\) rolling with velocity \(V\) along a line parallel to \(PJ\) and \(B\) rolling so as to strike \(A\), the line of centres being at the moment of impact in the direction of the motion of \(B\). After the collision, \(A\) rolls on into the pocket at \(J\). Find the initial velocity of \(B\) in magnitude and direction, assuming that the coefficient of restitution between the balls is \(\frac{1}{2}\), and that their diameters can be neglected.

A uniform rod of mass \(M\) and length \(2a\) lies on a smooth horizontal table, and is free to rotate about a vertical axis through its mid-point. When the rod is at rest, a small frog of mass \(m\) leaps from one end of the rod with velocity \(\sqrt{(\lambda ag)}\), in such a direction that the angle between the plane of his trajectory and the initial position of the rod is \(\theta\), where \(0 < \theta < \pi/2\). Show that if he is able, by suitable choice of the angle of elevation of his jump, to alight on the other end of the rod as it comes round for the first time, then \[ M<3m, \quad \lambda \ge 2 \cos\theta, \] and \(\theta\) is the angle defined by \[ \theta = \frac{3m}{2M}\sin 2\theta. \]

(i) Given that the product of two of the roots is 2, solve the equation \[ x^4+2x^3-14x^2-11x-2=0. \] (ii) Show that if \(a\) is a root of the equation \[ x^4+3x^3-6x^2-3x+1=0 \] then so also is \(\frac{a-1}{a+1}\). Express the remaining roots in terms of \(a\), and hence, or otherwise, solve the equation completely.