Difference between revisions of "1969 Canadian MO Problems/Problem 9"
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− | Note that the shortest side would subtend the smallest angle at the center of the circle. It is easily provable that this angle is <math>90^{circ} </math>, because had all 4 angles been greater than <math>90^{circ} </math>, the sum of the subtended angles would have been greater than <math>360^{circ} </math>, which is impossible as the sum should be exactly <math>360^{circ} </math>. Hence, atleast one (but not all 4) of the angles would be less than or equal to <math>90^{circ} </math> and so the smallest one most certainly is also <math>\leq 90^{circ} </math>. | + | Note that the shortest side would subtend the smallest angle at the center of the circle. It is easily provable that this angle is <math>90^{\circ} </math>, because had all 4 angles been greater than <math>90^{\circ} </math>, the sum of the subtended angles would have been greater than <math>360^{\circ} </math>, which is impossible as the sum should be exactly <math>360^{\circ} </math>. Hence, atleast one (but not all 4) of the angles would be less than or equal to <math>90^{\circ} </math> and so the smallest one most certainly is also <math>\leq 90^{\circ} </math>. |
− | Now assuming the angle between the two radii at the ends of the smallest side is <math>\theta </math>, the length of the smallest side is <math>\sqrt{2 - 2 cos | + | Now assuming the angle between the two radii at the ends of the smallest side is <math>\theta </math>, the length of the smallest side is <math>\sqrt{2 - 2 cos \theta} </math>. Since <math>cos \theta </math> is positive in the interval <math>(0, 90^{\circ}) </math>, <math>2- 2 cos \theta \leq 2 </math> and so <math>\sqrt{2 - 2 cos \theta } \leq \sqrt{2} </math>. |
{{Old CanadaMO box|num-b=8|num-a=10|year=1969}} | {{Old CanadaMO box|num-b=8|num-a=10|year=1969}} |
Latest revision as of 10:53, 28 May 2024
Problem
Show that for any quadrilateral inscribed in a circle of radius the length of the shortest side is less than or equal to .
Solution 1
Let be the edge-lengths and be the lengths of the diagonals of the quadrilateral. By Ptolemy's Theorem, . However, each diagonal is a chord of the circle and so must be shorter than the diameter: and thus .
If , then which is impossible. Thus, at least one of the sides must have length less than , so certainly the shortest side must.
Solution 2
Note that the shortest side would subtend the smallest angle at the center of the circle. It is easily provable that this angle is , because had all 4 angles been greater than , the sum of the subtended angles would have been greater than , which is impossible as the sum should be exactly . Hence, atleast one (but not all 4) of the angles would be less than or equal to and so the smallest one most certainly is also .
Now assuming the angle between the two radii at the ends of the smallest side is , the length of the smallest side is . Since is positive in the interval , and so .
1969 Canadian MO (Problems) | ||
Preceded by Problem 8 |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • | Followed by Problem 10 |