Difference between revisions of "Ceva's Theorem"
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== Statement == | == Statement == | ||
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A necessary and sufficient condition for AD, BE, CF, where D, E, and F are points of the respective side lines BC, CA, AB of a triangle ABC, to be concurrent is that | A necessary and sufficient condition for AD, BE, CF, where D, E, and F are points of the respective side lines BC, CA, AB of a triangle ABC, to be concurrent is that | ||
<br><center><math>BD * CE * AF = +DC * EA * FB</math></center><br> | <br><center><math>BD * CE * AF = +DC * EA * FB</math></center><br> |
Revision as of 15:03, 23 June 2006
Ceva's Theorem is an algebraic statement regarding the lengths of cevians in a triangle.
Contents
Statement
http://billydorminy.homelinux.com/aopswiki/cevathm.png
A necessary and sufficient condition for AD, BE, CF, where D, E, and F are points of the respective side lines BC, CA, AB of a triangle ABC, to be concurrent is that
where all segments in the formula are directed segments.
Proof
Let be points on respectively such that are concurrent, and let be the point where , and meet. Draw a parallel to through the point . Extend until it intersects the parallel at a point . Construct in a similar way extending .
The triangles and are similar, and so are and . Then the following equalities hold:
and thus
Notice that if directed segments are being used, then and have opposite signs, and therefore when cancelled change the sign of the expression. That's why we changed to .
Now we turn to consider the following similarities: and . From them we get the equalities
which lead to
Multiplying the last expression with (1) gives
and we conclude the proof.
To prove the converse, suppose that are points on respectively and satisfying
Let be the intersection point of with , and let be the intersection of with . Since then are concurrent, we have
and thus
which implies , and therefore are concurrent.
Example
Suppose AB, AC, and BC have lengths 13, 14, and 15. If and . Find BD and DC.
If and , then , and . From this, we find and .