Centroid

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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 is (a,b), where a is the arithmetic average of the x-coordinates of the vertices of the triangle and b is the arithmetic average 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 parallelograms bisect each other, we have $\displaystyle GE = E'G = BE'$, or $\displaystyle BG = 2GE$. Hence each median passes through a similar trisection point of any other median; hence 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