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Maxwell Theorem via the Center of GravityMichel Cabart
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| Given ΔABC and a point G, the sides of ΔMNP are parallel to the cevians in ΔABC through G. Then the cevians in ΔMNP parallel to the sides of ΔABC are concurrent. |
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Below, the vector joining point A to B will be written in bold, so that, for example,
In ΔABC with A', B', C' on sides opposite the vertices A, B, and C, the fact that the cevians AA', BB', CC' concur in point G is equivalent to either of the two conditions:
| There is a triple of real numbers | |
| (1) | aGA + bGB + cGC = 0 |
| There is a triple of real numbers | |
| (2) |
A' = Z(B, b; C, c) B' = Z(A, a; C, c) C' = Z(A, a; B, b), |
where Z(X, x; Y, y) denotes the barycenter of two material points X and Y with masses x at X and y at Y.
Let's suppose lines AA', BB' and CC' intersect.
Step 1: NP, PM, MN are parallel to GA, GB, GC means there exists x, y, z such that
Step 2: MM', NN', PP' are parallel to BC, AC, AB meaning there is
| MM' = m(GC - GB) = (m/c)MN + (m/b)MP |
so that
| M' = Z(N, 1/c; P, 1/b) = Z(N, b; C, c) |
by multiplying by bc. Similarly,
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N' = Z(M, a; P, c) and P' = Z(M, a; N, b). |
This proves the theorem thanks to (2).
Barycenter and Barycentric Coordinates
- 3D Quadrilateral - a Coffin Problem
- Barycentric Coordinates
- Barycentric Coordinates: a Tool
- Barycentric Coordinates and Geometric Probability
- Ceva's Theorem
- Determinants, Area, and Barycentric Coordinates
- Maxwell Theorem via the Center of Gravity
- Medians in a Quadrilateral
- Three glasses puzzle
- Van Obel Theorem and Barycentric Coordinates
Copyright © 1996-2008 Alexander Bogomolny
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