\nopagenumbers \noindent {\bf 43rd IMO 2002} \vskip 25pt \noindent {\bf A1}. $S$ is the set of all $(h, k)$ with $h, k$ non-negative integers such that $h+k < n$. Each element of $S$ is colored red or blue, so that if $(h, k)$ is red and $h' \le h, k' \le k$, then $(h', k')$ is also red. A type 1 subset of $S$ has $n$ blue elements with different first member and a type 2 subset of $S$ has $n$ blue elements with different second member. Show that there are the same number of type 1 and type 2 subsets. \vskip 12pt \noindent {\bf A2}. $BC$ is a diameter of a circle center $O$. $A$ is any point on the circle with $\angle AOC > 60^o. \ EF$ is the chord which is the perpendicular bisector of $AO. \ D$ is the midpoint of the minor arc $AB$. The line through $O$ parallel to $AD$ meets $AC$ at $J$. Show that $J$ is the incenter of triangle $CEF$. \vskip 12pt \noindent {\bf A3}. Find all pairs of integers $m > 2, n > 2$ such that there are infinitely many positive integers $k$ for which $k^n + k^2 - 1$ divides $k^m + k-1$. \vskip 12pt \noindent {\bf B1}. The positive divisors of the integer $n > 1$ are $d_1 < d_2 < \ldots < d_k$, so that $d_1 = 1, d_k = n$. Let $d = d_1 d_2 + d_2 d_3 + \cdots + d_{k-1}d_k$. Show that $d < n^2$ and find all $n$ for which $d$ divides $n^2$. \vskip 12pt \noindent {\bf B2}. Find all real-valued functions on the reals such that $(f(x) + f(y)) ((f(u) + f(v)) = f(xu - yv) + f(xv + yu)$ for all $x, y, u, v$. \vskip 12pt \noindent {\bf B3}. $n > 2$ circles of radius 1 are drawn in the plane so that no line meets more than two of the circles. Their centers are $O_1, O_2, \cdots , O_n$. Show that $\sum_{i