calculating perpendicular and angular distance between line segments in 3d

I am working on implementing a clustering algorithm in C++. Specifically, this algorithm: http://www.cs.uiuc.edu/~hanj/pdf/sigmod07_jglee.pdf

At one point in the algorithm (sec 3.2 p4-5), I am to calculate perpendicular and angular distance (d┴ and dθ) between two line segments: p1 to p2, p1 to p3.

It has been a while since I had a math class, I am kinda shaky on what these actually are conceptually and how to calculate them. Can anyone help?

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To get the perpendicular distance of a point `Q` to a line defined by two points `P_1` and `P_2` calculate this:

``````d = DOT(Q, CROSS(P_1, P_2) )/MAG(P_2 - P_1)
``````

where `DOT` is the dot product, `CROSS` is the vector cross product, and `MAG` is the magnitude (`sqrt(X*X+Y*Y+..)`)

Using Fig 5. You calculate `d_1` the distance from `sj` to line (`si->ei`) and `d_2` the distance from `ej` to the same line.

I would establish a coordinate system based on three points, two (`P_1`, `P_2`) for a line and the third `Q` for either the start or the end of the other line segment. The three axis of the coordinate system can be defined as such:

``````e = UNIT(P_2 - P_1)      // axis along the line from P_1 to P_2
k = UNIT( CROSS(e, Q) )  // axis normal to plane defined by  P_1, P_2, Q
n = UNIT( CROSS(k, e) )  // axis normal to line towards Q
``````

where `UNIT()` is function to return a unit vector (with magnitude=1).

Then you can establish all your projected lengths with simple dot products. So considering the line `si-ei` and the point `sj` in Fig 5, the lengths are:

``````(l || 1) = DOT(e, sj-si);
(l |_ 1) = DOT(n, sj-si);
ps = si + e * (l || 1)      //projected point
``````

And with the end of the second segment `ej`, new coordinate axes (`e`,`k`,`n`) need to be computed

``````(l || 2) = DOT(e, ei-ej);
(l |_ 1) = DOT(n, ej-ei);
pe = ei - e * (l || 1)      //projected point
``````

Eventually the angle distance is

``````(d th)  = ATAN( ((l |_ 2)-(L |_ 1))/MAG(pe-ps) )
``````

PS. You might want to post this at Math.SO where you can get better answers.

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This isn't really what I asked. I'm not looking for a perpendicular distance between a point and a line segment, but between two line segments. But I will take a look over at Math.SO, thanks. – basil Mar 7 '11 at 19:10
Two line segments are not necessarily in a plane to derive the perpendicular distance. I gave you an algorithm above to compute all those values in Fig 5 of the paper, but I guess you are not really following the logic above. IMHO you need a good grasp of 3D geometry to tackle such a project. – ja72 Mar 7 '11 at 19:20
umm, what is math.so btw? – basil Mar 7 '11 at 19:21
I guess it is math.SE not math.SO - math.stackexchange.com. Sorry too much overflow! – ja72 Mar 7 '11 at 19:38

Look at figure 5 on page 3. It draws out what d┴ and dθ are.

EDIT: The "Lehmer mean" is defined using Lp-space conventions. So in 3 dimensions, you would use p = 3. Let's say that the (Euclidean) distance between the two start points is d1, and between the ends is d2. Then `d┴(L1, L2) = (d1^3 + d2^3) / (d1^2 + d2^2)`.

To find the angle between two vectors, you can use their dot product. The norm (denoted `||x||`) is computed like this.

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It shows it on 2D. The question is in 3D, I think – ja72 Mar 7 '11 at 18:03
well it speaks of d-dimensions but it defines lehmer means in very vague terms and it gives no real discernable method for determinding the angle between the two line segments. i suppose it could be done with some trigonometry but i dont quite know how to extrapolate that out to 3d. – basil Mar 7 '11 at 18:46
@basil: I've tried to clear it up, let me know if you still have questions. – Xodarap Mar 7 '11 at 19:31
Thank you. I think I kinda conceptually grasp it. I am looking on how to calculate euclidean distances right now. If you have any references for how to do that, it'd be great. Its been about 10 years since I took linear algebra and this stuff is coming back painfully slow. – basil Mar 7 '11 at 19:54
@basil: See wikipedia. "Euclidean distance" is just what everyone else calls "distance." – Xodarap Mar 7 '11 at 19:58