From Wikipedia, the free encyclopedia

In geometry, the centroid or barycenter of an object X in n-dimensional space is the intersection of all hyperplanes that divide X into two parts of equal moment about the hyperplane. Informally, it is the "average" of all points of X.

The geometric centroid of a physical object coincides with its center of mass if the object has uniform density, or if the object's shape and density have a symmetry which fully determines the centroid. These conditions are sufficient but not necessary.

Contents 1 Centroid of triangle and tetrahedron 2 Centroids of cones and pyramids 3 Centroid and convexity 4 Integral formula 5 Center of symmetry 6 References 7 See also 8 External links

The centroid of a triangle is the point of intersection of its medians (the lines joining each vertex with the midpoint of the opposite side). The centroid divides each of the medians in the ratio 2:1. The centroid is also located 1/3 of the perpendicular distance between each side and the opposing point. (As illustrated in the figures to the right).

The centroid is the triangle's center of mass if the triangle is made from a uniform sheet of material. Its Cartesian coordinates are the means of the coordinates of the three vertices. That is, if the three vertices are located at (x_a,y_a), (x_b,y_b), and (x_c,y_c), then the centroid is at

A similar result holds for a tetrahedron: its centroid is the intersection of all line segments that connect each vertex to the centroid of the opposite face. These line segments are divided by the centroid in the ratio 2:1. The result generalizes to any n-dimensional simplex in the obvious way. If the set of vertices of a simplex is v₀,...,v_n, then considering the vertices as vectors, the centroid is at

The isogonal conjugate of a triangle's centroid is its symmedian point.

The centroid of a cone or pyramid is located on the line segment that connects the apex to the centroid of the base, and divides that segment in the ratio 3:1.

The centroid of a convex object always lies in the object. A concave object might have a centroid that is outside the figure itself. The centroid of a ring or a bowl, for example, lies in the object's central void.

The abscissa of the centroid of a plane figure can be given as the integral , where f(x) is the vertical extent of the object at abscissa x. This formula can be derived from the first moment about the y-axis of the area.

The same formula yields the first coordinate of the centroid of an object in , for any dimension n, provided that f(x) is the (n − 1)-dimensional measure of the object's cross-section at coordinate x — that is, the set of all points in the object whose first coordinate is x.

Note that the denominator is simply the object's n-dimensional measure. In the special case where f is normalized, i. e. the denominator is 1, the centroid is called the mean of f.

The formula cannot be applied if the object has zero measure, or if either integral diverges.

If the centroid is defined, it is a fixed point of all isometries in its symmetry group. Thus symmetry may fully or partially determine the centroid, depending on the kind of symmetry. It also follows that for an object with translational symmetry the centroid is undefined, because a translation has no fixed point.

• Abdi, H. "[1] ((2007). Centroid, center of gravity, center of mass, barycenter. In N.J. Salkind (Ed.): Encyclopedia of Measurement and Statistics. Thousand Oaks (CA): Sage.".

• Center of mass
• List of centroids
• Pappus's centroid theorem

• Encyclopedia of Triangles Centers by Clark Kimberling. The centroid is indexed as X(2).
• Triangle centers by Antonio Gutierrez from Geometry Step by Step from the Land of the Incas.
• Characteristic Property of Centroid at cut-the-knot
• Barycentric Coordinates at cut-the-knot
• Centroid of a triangle With interactive applet and animation