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USAJMO Problem 1
Given a triangle , let and be points on segments and , respectively, such that . Let and be distinct points on segment such that lies between and , , and . Prove that , , , are concyclic (in other words, these four points lie on a circle).
Problem 2
Find all integers such that among any positive real numbers , , , with there exist three that are the side lengths of an acute triangle.
Problem 3
Let , , be positive real numbers. Prove that
Problem 4
Let be an irrational number with , and draw a circle in the plane whose circumference has length 1. Given any integer , define a sequence of points , , , as follows. First select any point on the circle, and for define as the point on the circle for which the length of arc is , when travelling counterclockwise around the circle from to . Supose that and are the nearest adjacent points on either side of . Prove that .
Solution outline
Use mathematical induction. For it is true because one point can't be closest to in both ways, and that . Suppose that for some , the nearest adjacent points and on either side of satisfy . Then consider the nearest adjacent points and on either side of . It is by the assumption of the nearness we can see that either , , or one of or equals two . Let's consider the following two cases.
(i) Suppose .
Since the length of the arc is (where equals to subtracted by the greatest integer not exceeding ) and length of the arc is , we now consider a point which is defined by traveling clockwise on the circle such that the length of arc is . We claim that either is on the interior of the arc or on the interior of the arc . Algebraically, it is equivalent to either or . Suppose the former fails, i.e. . Then suppose and , where , are integers and . We now have and Therefore is either closer to on the side, or closer to on the side. Hence or is , therefore
(ii) Suppose Then either when and , or when one of or is .
In either case, is true.
Problem 5
For distinct positive integers , , define to be the number of integers with such that the remainder when divided by 2012 is greater than that of divided by 2012. Let be the minimum value of , where and range over all pairs of distinct positive integers less than 2012. Determine .
Problem 6
Let be a point in the plane of triangle , and a line passing through . Let , , be the points where the reflections of lines , , with respect to intersect lines , , , respectively. Prove that , , are collinear.