# quality analysis of fitted pyramid

sorry for posting this in programing site, but there might be many programming people who are professional in geometry, 3d geometry... so allow this.

I have been given best fitted planes with the original point data. I want to model a pyramid for this data as the data represent a pyramid. My approach of this modeling is

1. Finding the intersection lines (e.g. AB, CD,..etc) for each pair of adjacent plane
2. Then, finding the pyramid top (T) by intersecting the previously found lines as these lines don’t pass through a single point
3. Intersecting the available side planes with a desired horizontal plane to get the basement

In figure – black triangles are original best fitted triangles; red and blue triangles are model triangles

I want to show that the points are well fitted for the pyramid model than that it fitted for the given best fitted planes. (Assume original planes are updated as shown)

Actually step 2 is done using weighted least square process. Each intersection line is assigned with a weight. Weight is proportional to the angle between normal vectors of corresponding planes. in this step, I tried to find the point which is closest to all the intersection lines i.e. point T. according to the weights, line positions might change with respect to the influence of high weight line. That mean, original planes could change little bit. `So I want to show that these new positions of planes are well fitted for the original point data than original planes.`

Any idea to show this? I am thinking to use RMSE and show before and after RMSE. But again I think I should use weighted RMSE as all the planes refereeing to the point T are influenced so that I should cope this as a global case rather than looking individual planes….. But I can’t figure out a way to show this. Or maybe I should use some other measure… So, I am confused and no idea to show this.. Please help me…

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you would be better off removing the C++ tag and adding the math and geometry tags – mathematician1975 Oct 23 '12 at 14:40
@mathematician1975: thanks i did – niro Oct 23 '12 at 14:46
Sorry but your question is quite cloudy. I've read it twice but was unable to even understand the initial process. Maybe you want to rework your question. A good start would be to take care of case sensitivity. Also some figures could be helpful. – AD-530 Oct 23 '12 at 17:32
Do you want to find out whether the second step made the fit better? Or do you want to compose an argument that the second step made the fit better, even if it really didn't? – Beta Oct 23 '12 at 21:37
Solve a simpler problem first: you have some points that belong on a plane. You have two candidate planes. How can you show that one is better than the other? If sum-of-squares doesn't convince you, then what can? – Beta Oct 23 '12 at 22:46

If you are given the best-fit planes, why not intersect the three of them to get a single unambiguous `T`, then determine the lines `AT`, `BT`, and `CT`?

This is not a rhetorical question, by the way. Your actual question seems to be for reassurance that your procedure yields "well-fitted" results, but you have not explained or described what kind of fit you're looking for!

Unfortunately, without this information, your question cannot be answered as asked. If you describe your goals, we may be able to help you achieve them -- or, if you have not yet articulated them for yourself, that exercise may be enough to let you answer your own question...

That said, I will mention that the only difference between the planes you started with and the planes your procedure ends up with should be due to floating point error. This is because, geometrically speaking, all three lines should intersect at the same point as the planes that generated them.

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I think you missed the point. The three starting planes are not necessarily intersecting in one point. So it's not possible to just intersect them and get T. – AD-530 Oct 24 '12 at 7:34
@AD-530: any idea to prove this sir.. do you think my step2 enhances the original planes? – niro Oct 24 '12 at 8:58
@comingstorm: originally planes are fitted using Hough tranform but small distance threshold is given when fitting the planes by Hough. yes, as AD-530 told lines are not passing one point. i am not sure that i got your point... actually i did least square fit...but i am thinking that step2 further enhances the fitting accuracy of orginal planes.. what do you think? how to prove this.. – niro Oct 24 '12 at 9:51
Unless the intersection lines happen to be exactly parallel, three 3D planes always intersect in exactly one point. How do you figure that they dont? – comingstorm Oct 24 '12 at 10:13
Uh yes, your'e right! Sorry, my mistake – AD-530 Oct 24 '12 at 10:30