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I have this set of x and y coordinates:


and I want to calculate the ellipsoid that contains this set of points, I use the function ellipsoidhull() in the package "cluster", and I get:

> ellipsoidhull(d)
'ellipsoid' in 2 dimensions:`
 center = ( 2.00108 0.36696 ); squared ave.radius d^2 =  2`
and shape matrix =
x 0.66590 0.233106
y 0.23311 0.095482
  hence, area  =  0.60406

However it's not obvious to me how I can get from these results, the lengths of the semi-major axes of this ellipse.

Any idea?

Thank you very much in advance.


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Might be worth reading thru this question stackoverflow.com/questions/3417028/… and the links there for some info on relating the eigenvalues of the covariance matrix to the axes of the ellipse. –  Carl Witthoft Aug 16 '13 at 17:28
user18441 I treat the question as a geometrical problem, so maybe it is worth that you read the link showed in the above comment and use better tools ( statistical tools) to deal with it. –  agstudy Aug 16 '13 at 17:39
Even better, the wikipedia page "ellipsoid" defines the shape matrix in terms of the axes (via the eigenvalues), so you should be able to calculate the radii explicitly. –  Carl Witthoft Aug 16 '13 at 17:42

2 Answers 2

up vote 3 down vote accepted

The square of the semi-axes are the eigenvalues of the shape matrix, times the average squared radius.

x <- c(1.798805,2.402390,2.000000,3.000000,1.000000)
y <- c(0.3130147,0.4739707,0.2000000,0.8000000,0.1000000)
d <- cbind( x, y )
r <- ellipsoidhull(d)
plot( x, y, asp=1, xlim=c(0,4) )
lines( predict(r) )
e <- sqrt(eigen(r$cov)$values)
a <- sqrt(r$d2) * e[1]  # semi-major axis
b <- sqrt(r$d2) * e[2]  # semi-minor axis
theta <- seq(0, 2*pi, length=200)
lines( r$loc[1] + a * cos(theta), r$loc[2] + a * sin(theta) )
lines( r$loc[1] + b * cos(theta), r$loc[2] + b * sin(theta) )
share|improve this answer
Thank you Vincent. Sorry my ignorance. "a" and "b" the lengths of the axes of the ellipse and therefore to get the semi-axes they need to be divided by 2. Is this correct? –  user18441 Aug 16 '13 at 18:33
Yeah yeah, steal my commments-answer :-). Very nice details in this code. –  Carl Witthoft Aug 16 '13 at 19:02
@user18441: the comments in my code were incorrect, these are already the semi-axes -- no need to divide by 2. –  Vincent Zoonekynd Aug 16 '13 at 19:21
Thank you very much Vincent! –  user18441 Aug 16 '13 at 19:24

You can do this:

exy <- predict(ellipsoidhull(d)) ## the ellipsoid boundary
me <- colMeans((exy))            ## center of the ellipse

Then you compute the minimum and maximum distance to get respectively minor and major axis:

dist2center <- sqrt(rowSums((t(t(exy)-me))^2))
max(dist2center)     ## major axis
[1] 1.264351
> min(dist2center)   ## minor axis
[1] 0.1537401

EDIT plot the ellipse with the axis:

lines(rbind(me,exy[dist2center == min(dist2center),]))
lines(exy[dist2center == max(dist2center),])

enter image description here

share|improve this answer
Thank you agstudy! to plot them I guess I need to trace a line between the center of the ellipse and the point the furthest away and the closest from it. Any idea of how this could be easily be done? –  user18441 Aug 16 '13 at 17:26
@user18441 yes. you can see my edit. –  agstudy Aug 16 '13 at 17:33
thank you so much! –  user18441 Aug 16 '13 at 17:37
Heh. An entirely geometry-free solution. Is perhaps me <- colMeans((exy)) a better center? The interior points in the sample shouldn't contribute, I think. –  BondedDust Aug 16 '13 at 17:45
@DWin right. I edit my answer. But, For some reasons I get 2 points for the max but only one point for the min. –  agstudy Aug 16 '13 at 17:54

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