Difference between revisions of "1992 IMO Problems/Problem 4"
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<math>Line_{PR}\colon \; y+r=\frac{-2r(m+d)}{(m+d)^{2}-r^2)}\left( x-(m+d) \right)</math> | <math>Line_{PR}\colon \; y+r=\frac{-2r(m+d)}{(m+d)^{2}-r^2)}\left( x-(m+d) \right)</math> | ||
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+ | Now we get the coordinates of point <math>S=(S_{x},S_{y})</math>, we solve the following equations: | ||
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+ | <math>S_{x}^{2}+S_{y}^2=r^{2}</math> | ||
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+ | <math>\left| QT \right|^{2}=(m-d-S_{x})^{2}+(r+S_{y})^2</math> | ||
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+ | <math>(m-d)^{2}=(m-d-S_{x})^{2}+(r+S_{y})^2</math> | ||
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+ | After a lot of algebra, this solves to: | ||
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+ | <math>S_{x}=\frac{2r^{2}(m-d)}{(m-d)^{2}+r^{2}}</math> | ||
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+ | <math>S_{y}=\frac{r\left[ (m-d)^{2}-r^{2} \right]}{(m-d)^{2}+r^{2} }</math> | ||
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+ | Now we calculate the slope of the line that passes through <math>PQ</math> which is perpendicular to the line that passes from the center of the circle to point <math>S</math> as follows: | ||
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+ | <math>Slope_{PQ}=\frac{-S_{x}}{S_{y}}=\frac{-2r(m-d)}{(m-d)^{2}-r^2)}</math> | ||
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+ | Then, the equation of the line that passes through <math>PQ</math> is as follows: | ||
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+ | <math>Line_{PQ}\colon \; y+r=\frac{-2r(m-d)}{(m-d)^{2}-r^2)}\left( x-(m-d) \right)</math> | ||
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Revision as of 17:15, 12 November 2023
Problem
In the plane let be a circle, a line tangent to the circle , and a point on . Find the locus of all points with the following property: there exists two points , on such that is the midpoint of and is the inscribed circle of triangle .
Video Solution
https://www.youtube.com/watch?v=ObCzaZwujGw
Solution
Note: This is an alternate method to what it is shown on the video. This alternate method is too long and too intensive in solving algebraic equations. A lot of steps have been shortened in this solution. The solution in the video provides a much faster solution,
Let be the radius of the circle .
We define a cartesian coordinate system in two dimensions with the circle center at and circle equation to be
We define the line by the equation , with point at a distance from the tangent and cartesian coordinates
Let be the distance from point to point such that the coordinates for are and thus the coordinates for are
Let points , , and be the points where lines , , and are tangent to circle respectively.
First we get the coordinates for points and .
Since the circle is the incenter we know the following properties:
and
Therefore, to get the coordinates of point , we solve the following equations:
After a lot of algebra, this solves to:
Now we calculate the slope of the line that passes through which is perpendicular to the line that passes from the center of the circle to point as follows:
Then, the equation of the line that passes through is as follows:
Now we get the coordinates of point , we solve the following equations:
After a lot of algebra, this solves to:
Now we calculate the slope of the line that passes through which is perpendicular to the line that passes from the center of the circle to point as follows:
Then, the equation of the line that passes through is as follows:
In the plane let be a circle, a line tangent to the circle , and a point on . Find the locus of all points with the following property: there exists two points , on such that is the midpoint of and is the inscribed circle of triangle .
Alternate solutions are always welcome. If you have a different, elegant solution to this problem, please add it to this page.