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Centroid

Revision as of 11:27, 7 September 2006 by JBL (talk | contribs)

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The centroid of a triangle is the point of intersection of the medians of the triangle and is conventionally denoted $G$. The centroid has the special property that, for each median, the distance from a vertex to the centroid is twice that of the distance from the centroid to the midpoint of the side opposite that vertex. Also, the three medians of a triangle divide it into six regions of equal area. The centroid is the center of mass of the triangle; in other words, if you connected a string to the centroid of a triangle and held the other end of the string, the triangle would be level.

The coordinates of the centroid of a coordinatized triangle are $(a,b)$ where $a$ is the arithmetic mean of the $x$-coordinates of the vertices of the triangle and $b$ is the arithmetic mean of the $y$-coordinates of the triangle.


Centroid.PNG


Proof of concurrency of the medians of a triangle

Note: The existance of the centroid is a trivial consequence of Ceva's Theorem. However, there are many interesting and elegant ways to prove its existance, such as those shown below.

Proof 1

Readers unfamiliar with homothety should consult the second proof.

Let $\displaystyle D,E,F$ be the respective midpoints of sides $\displaystyle BC, CA, AB$ of triangle $\displaystyle ABC$. We observe that $\displaystyle DE, EF, FE$ are parallel to (and of half the length of) $\displaystyle AB, BC, CA$, respectively. Hence the triangles $\displaystyle ABC, DEF$ are homothetic with respect to some point $\displaystyle G$ with dilation factor $\displaystyle -\frac{1}{2}$; hence $\displaystyle AD, BE, CF$ all pass through $\displaystyle G$, and $\displaystyle AG = 2 GD; BG = 2 GE; CG = 2 GF$. Q.E.D.

Proof 2

Let $\displaystyle ABC$ be a triangle, and let $\displaystyle D,E,F$ be the respective midpoints of the segments $\displaystyle BC, CA, AB$. Let $\displaystyle G$ be the intersection of $\displaystyle BE$ and $\displaystyle CF$. Let $\displaystyle E',F'$ be the respective midpoints of $\displaystyle BG, CG$. We observe that both $\displaystyle EF$ and $\displaystyle E'F'$ are parallel to $\displaystyle CB$ and of half the length of $\displaystyle CB$. Hence $\displaystyle EFF'E'$ is a parallelogram. Since the diagonals of a parallelogram bisect each other, we have $\displaystyle GE = E'G = BE'$, or $\displaystyle BG = 2GE$. Hence each median passes through an appropriate trisection point of each other median and the medians concur. Q.E.D.

We note that both of these proofs give the result that the distance of a vertex of a point of a triangle to the centroid of the triangle is twice the distance from the centroid of the traingle to the midpoint of the opposite side.

See also

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