# How should I create an algorithm for the centroid of any System.Windows.Media.Geometry object?

I plan on having to split up the Geometry object into a series of simpler shapes, and combine their centroids using this formula:

Mathematical details of this formula can be found in this Wikipedia article.

NOTICE: Don't be suprised if my view of the mathematics is incorrect. I haven't done any complex math past trigonometry, and I've never had to deal with Greek letters. I think I understand this one pretty well, but please just let me know if I've got it wrong.

An informational note: the centroid of a gometric shape or prism is not just the middle of the shape. It is the center of gravity, or center of mass. I assume that Geometry objects can encapsulate 3D prisms as well, so I may have to take this into account in the future, but for now I'm focusing on 2D Geometries only. For a 2D shape you have to imagine it being a stiff piece of paper with a given shape, and the centroid would be the point at which this piece of paper would balance on a needle.

The first problem I'm faced with is that I need to find a way to accurately split any given Geometry object into simple-enough shapes, so this formula can work correctly. Does anyone have any ideas how this might be accomplished? Or is there a better procedure that will still work universally?

The second problem I'm faced with is that after the geometry is split up, how do I go about finding the centroid of each piece? Each type of simple shape (triangle, quadrilateral, semicircle, etc) has its own centroid formula. Is there a way for me to figure which type of shape each piece is?

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There is no universal formula, only shape-specific. –  Lance Roberts Aug 24 '09 at 20:36
Thanks, Lance. I'll edit that part out. –  Giffyguy Aug 24 '09 at 20:48
Your view of the math is correct. –  duffymo Aug 25 '09 at 1:23

Tesselation or discretization of arbitrary 2D planar shapes is a common problem in finite element analysis. It's commonly done with planar triangles or quadrilaterals. Try a Google search on "2d finite element mesh generation" or quadtree or octree mesh generation. You can calculate the centroid of each simple shape and apply the (correct) formula that you cited.

Something like this. Or these. You'd have to supply the raw geometry for the body in question, of course.

You've a long row to hoe yet. You'll have to do all of the following:

1. Find an auto meshing program and learn how to input the geometry for your 2D shape.
2. Run the auto mesher and get a mesh output which will consist of all the 2D points in space and the connectivities of all the triangular and quadrilateral elements.
3. Write a program to read in the mesh and calculate the area and centroid of each element.
4. Plug those values into the formula you cited to calculate the centroid of your original 2D shape. This means looping over all the elements and accumulating the areas an the products of the (x,y) coordinates of each element centroid and its area.
5. Once you have an answer, you need to check convergence. You do this by refining your mesh by making the elements smaller and recalculating. You know you've converged when you refine the mesh and the answers change by less than a small tolerance (5% or whatever you're willing to tolerate).

It's still a fair amount of work.

UPDATE: This one looks quite good, and it's open source.

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Interesting... I'll have to try these out and see what they can do. –  Giffyguy Aug 25 '09 at 4:18
This looks like an aweome solution, and it's basically the road I want to take - but what I really want is to figure out how to calculate the mesh myself. Do you know where I can find this algorithm anywhere? –  Giffyguy Aug 25 '09 at 20:09
Google for "finite element automatic mesh triangle" and pick the most detailed one you can find. Could take a while to code - it won't be trivial. You might want to just use something that exists: www-users.informatik.rwth-aachen.de/~roberts/software.html –  duffymo Aug 25 '09 at 22:19