# algorithm 3D point cloud volume calculation

I´m searching for a method to calculate the volume of a three-dimensional irregular object in either python or R. I have a time series of files (around 50 per sequence), equally spaced in time. They consist of a triangular mesh representation of the object with a fixed number of triangles. The vertices have known x,y,z-coordinates. There is no need for regenerating the mesh. And no need for visualization. The triangles have indices, the points as well. The object is not necessarily completely convex. But there are no unnecessary points. All known points are part of the hull. Now, I would like to calculate the volume of the object at each time point.

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The `cluster` pacakge in R has a `volume` function –  James Sep 14 '12 at 10:55
Hmmm, not really what I´m looking for. The function is restricted to ellipsoids (as far as I can see). And it´s more a point cloud problem, than a statistical one. –  Doc Sep 14 '12 at 11:05
Can't you immerse your computer into your bathtub and shout "Eureka!"? –  Roman Luštrik Sep 14 '12 at 11:21
Kidding aside, this sounds like an interesting problem. What I would do is "slice" the object in one dimension, interpolate points and do a Monte Carlo integration to find the area under the "slice". Sum by all slices and you should get the (normalized?) volume. –  Roman Luštrik Sep 14 '12 at 11:24
This sounds similar: stackoverflow.com/questions/1406029/… –  Bitwise Sep 14 '12 at 11:31

After some googling I found that this algorithm should do the trick for the closed mesh you are describing: iterate over all your triangles and sum up `dot(v0, cross(v1, v2)) / 6` where `v0`, `v1`, and `v2` are the coordinates of the triangle's vertices.
If your hull is a closed surface, then this should work as long as your triangles `(v0,v1,v2)` are oriented consistently (e.g., counterclockwise as seen from the outside of the surface). `cross()` is a vector cross product. The formula computes the signed volume of the tetrahedron `(origin,v0,v1,v2)`. Because it is signed, triangles facing toward the origin are subtracted from those facing away from it -- this is why consistent triangle orientation is essential. –  comingstorm Sep 14 '12 at 18:28
@Doc Like comingstorm said, `cross()` is the vector cross-product. Likewise, `dot()` is the vector dot-product. You can find the definitions of both of these operations on Wikipedia. As far as I can tell, the location of the origin in regards to your mesh shouldn't matter, as it is the relationship between the vertices that matters. I'm not sure though why triangles have to be consistently oriented, since the normals are not used in the calculation, and the signs are determined automatically. If I were you I'd test it on a few simple shapes (that you can easily know the volume of) first. –  Artyom Sep 18 '12 at 9:53