Difference between revisions of "1992 OIM Problems/Problem 5"

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As shown above, we draw a line and using the compass with the radius of the rhombus we draw a circle with center at any point on that line so that the circle cuts the line in two places.  This will be the diameter of the circle and the length of the diagonal of the trapezoid.  With the compass, we measure this diagonal with the compass and use it on the given circle <math>\Gamma</math> shown in green below:
 
As shown above, we draw a line and using the compass with the radius of the rhombus we draw a circle with center at any point on that line so that the circle cuts the line in two places.  This will be the diameter of the circle and the length of the diagonal of the trapezoid.  With the compass, we measure this diagonal with the compass and use it on the given circle <math>\Gamma</math> shown in green below:
  
[[File1992_OIM_P5d.png]]
+
[[File:1992_OIM_P5e.png]]
  
 
from any point on the given circle <math>\Gamma</math> shown in green and the compass with the diagonal measurement we draw an arc, shown in magenta, so that it cuts the green circle.
 
from any point on the given circle <math>\Gamma</math> shown in green and the compass with the diagonal measurement we draw an arc, shown in magenta, so that it cuts the green circle.

Revision as of 00:00, 20 December 2023

Problem

The circumference $C$ and the positive numbers $h$ and $m$ are given so that there is a trapezoid $ABCD$ inscribed in $C$, of height $h$ and in which the sum of the bases $AB$ and $CD$ is $m$. Build the trapezoid $ABCD$.

~translated into English by Tomas Diaz. ~orders@tomasdiaz.com

Solution

1992 OIM P5a.png

First we realize that the trapezoid is isosceles because it is inscribed in a circle. If we draw a rhombus using the midpoints of the trapezoid, the diagonals of the rhombus will be $m/2$ and $h$ We can construct such rhombus. Then, with similar triangles and the midpoints we know that the diagonal of the trapezoid is twice the length of the rhombus. Now we have all we need to start constructing:

1992 OIM P5b.png

Given the height $h$ in blue and length $m$ in red, we begin by bisecting with straight edge and compass the line of length $m$ and then bisecting it again as shown in the drawing above. We also bisect the blue line. Using the center of the blue line we measure $h/2$ with the compass and draw a circle at the center of the point of the second bisection of the red line as shown. Then we can construct the rhombus by joining the intersection of the second perpendicular bisector with the circles and the edge of red line with the middle as shown above.

We then measure the length of the rhombus with the compass and use that as a radius:

1992 OIM P5c.png

As shown above, we draw a line and using the compass with the radius of the rhombus we draw a circle with center at any point on that line so that the circle cuts the line in two places. This will be the diameter of the circle and the length of the diagonal of the trapezoid. With the compass, we measure this diagonal with the compass and use it on the given circle $\Gamma$ shown in green below:

1992 OIM P5e.png

from any point on the given circle $\Gamma$ shown in green and the compass with the diagonal measurement we draw an arc, shown in magenta, so that it cuts the green circle.

The point where it cuts is

  • Note. I actually competed at this event in Venezuela when I was in High School representing Puerto Rico. I'm proud to say that I got full points on this one and I solved it very quickly. I had a straight rule and compass kit which I used to solve it as we're supposed to build the trapezoid with it. Now, 3 decades later, I attempted this and spent a full 3 hours on it and couldn't solve it nor I remember what I did. I will attempt again some other time.

Alternate solutions are always welcome. If you have a different, elegant solution to this problem, please add it to this page.

See also

https://www.oma.org.ar/enunciados/ibe7.htm