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Title: Mutually Rational Distances Post by Aryabhatta on Dec 16th, 2004, 11:58am Show that we can find an infinite set of points S on the circumference of a circle of diameter 1, such that the distance between any two points of that set is rational. i.e given a circle C of diameter 1, Show existence of an S such that: if P [in] S then P lies on C. if P [in] S and Q [in] S then distance between P and Q is rational. S is not finite. Sorry if this problem has appeared before, but the search on this site has become really slow... |
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Title: Re: Mutually Rational Distances Post by Icarus on Dec 16th, 2004, 3:40pm Are we talking about intrinsic distance (arclength), or extrinsic distance (chordlength)? |
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Title: Re: Mutually Rational Distances Post by Aryabhatta on Dec 16th, 2004, 4:44pm on 12/16/04 at 15:40:23, Icarus wrote:
The chord length. If we consider the arc length, then it is not possible to have such an arrangement. (Pick any 3, add up the 3 arcs which complete the circle, we get that [pi] is rational) |
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Title: Re: Mutually Rational Distances Post by Icarus on Dec 16th, 2004, 7:58pm Actually, it is, but instead of being impossible, the solution is trivial: consider all points eir, for rational r, 0 [le] r < [pi]. Since the arclength between two points is measured by the shorter arc, the irrational longer arc between any two such points is immaterial. Still, trivial is no better than impossible in this regard. My request for clarification was unnecessary with a little thought. |
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Title: Re: Mutually Rational Distances Post by Barukh on Dec 17th, 2004, 12:54am Usually, drawings are not used in Putnam section, but in this particular case one comes handy. Take a segment AB of unit length, and construct a circle with AB as diameter. Next, draw a perpendicular line through A. Pick two points C, D on that line so that the lengths |AC|, |AD| are of the form where n, m are positive integers. Let C’, D’ be intersections of BC, BD with the circle. Then, |C’D’| is rational. To prove this, consider for instance points C, C’. Clearly, |BC| = (n2+m2)/2nm, hence rational. Because |BC| [cdot] |BC’| = 1 (why?), |BC’| = 2nm/(n2+m2), also rational. Then, |AC’| = (n2-m2)/(n2+m2), again rational. Analogously, |AD’|, |BD’| are rational. Now, look at the quadrilateral AC’D’B – it’s cyclic, and has 3 sides and 2 diagonals rational. According to Ptolemy’s theorem, the remaining side C’D’ should also be rational. To complete the proof of the problem’s statement, note that infinitely many points of the form (1) may be chosen on the line. |
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Title: Re: Mutually Rational Distances Post by Aryabhatta on Dec 17th, 2004, 10:41am Nicely done Barukh! The solution I have is similar. Consider diameter 1 circle centered at (0,0). Let P be (1/2,0) and Q be (-1/2,0) (End points of the horizontal diameter). Consider any two pythogarean (rational) triples (x1,y1,1) and (x2,y2,1) i.e xi2 + yi2 = 1. Picks points A1 and A2 on the 'top' semicircle of the circle such that |AiP| = xi and |AiQ| = yi. This is possible as AiPQ is a right angled triangle. (|XY| = distance between points X and Y) By Ptolemy's theorem, |A1A2| is rational. Since we have infinitely many such A's we are done. |
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Title: Re: Mutually Rational Distances Post by Barukh on Dec 18th, 2004, 9:16am The following related question is much harder: How many points can be drawn in the plane in general position (i.e. no 3 points on the same line, no 4 points on the same circle) so that their mutual distances are all integers? |
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