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I have a finite metric space given as a (symmetric) k by k distance matrix. I would like an algorithm to (approximately) isometrically embed this in euclidean space R^(k-1). While it is not always possible to do exactly by solving the system of equations given by the distances I am looking for a solution that embeds with some (very small) controllable error.

I currently use multidimensional scaling (MDS) with the output dimension set to (k-1). It occurs to me that in general MDS may be optimized for the situation where you are trying to reduce the ambient embedding dimension to something less then (k-1) (typically 2 or 3) and that there may be a better algorithm for my restricted case.

Question: What is a good/fast algorithm for realizing a metric space of size k in R^{k-1} using euclidean distance?

Some parameters and pointers:

(1) My k's are relatively small. Say 3 < k < 25

(2) I don't actually care if I embed in R^{k-1}. If it simplifies things/makes things faster any R^N would also be fine as long as it's isometric. I'm happy if there's a faster algorithm or one with less error if I increase to R^k or R^(2k+1).

(3) If you can point to a python implementation I'll be even happier.

(4) Anything better then MDS would work.

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Do your distances actually obey the triangle inequality? –  j_random_hacker Sep 29 '11 at 7:14
This might be better suited for math.stackexchange.com (probably not advanced enough for mathoverflow). –  celion Sep 29 '11 at 12:55
I am not sure if there is a faster algorithm than MDS that solves this in this setting. Where does your distance matrix come from? You might be better of immediately reducing the dimension of the data that you produced the distance matrix from (only if this is possible of course). –  LiKao Sep 29 '11 at 13:21
@j_random_hacker: Yes they do. It's a metric space link –  Anthony Bak Sep 29 '11 at 16:15
@LiKao: The distance matrix comes from the bottleneck distance between the persistent homology of a collection of point clouds. –  Anthony Bak Sep 29 '11 at 16:15

2 Answers 2

Why not try LLE , you can also find the code there.

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Ok, as promised here a simple solution:

Notation: Let d_{i,j}=d_{j,i} denote the squared distance between points i and j. Let N be the number of points. Let p_i denote the point i and p_{i,k} the k-th coordinate of the point.

Let's hope I derive the algorithm correctely now. There will be some explanations afterwards so you can check the derivation (I hate it when many indexes appear).

The algorithm uses dynamic programming to arrive at the correct solution

p_{i,k} := 0 for all i and k

for i = 2 to N do
   sum = 0
   for j = 2 to i - 1 do
     accu = d_{i,j} - d_{i,1} - p_{j,j-1}^2
     for k = 1 to j-1 do
       accu = accu + 2 p_{i,k}*p_{j,k} - p_{j,k}^2
     p_{i,j} = accu / ( 2 p_{j,j-1} )
     sum = sum + p_{i,j}^2
   p_{i,i-1} = sqrt( d_{i,0} - sum )

If I have not done any grave index mistakes (I usually do) this should do the trick.

The idea behind this:

We set the first point arbitrary at the origin to make our life easier. Not that for a point p_i we never set a coordinate k when k > i-1. I.e. for the second point we only set the first coordinate, for the third point we only set first and second coordinate etc.

Now let's assume we have coordinates for all points p_{k'} where k'<i and we want to calculate the coordinates for p_{i} so that all d_{i,k'} are satisfied (we do not care yet about any constraints for points with k>k'). If we write down the set of equations we have

d_{i,j} = \sum_{k=1}^N (p_{i,k} - p_{j,k} )^2

Because both p_{i,k} and p_{j,k} are equal to zero for k>k' we can reduce this to:

d_{i,j} = \sum_{k=1}^k' (p_{i,k} - p_{j,k} )^2

Also note that by the loop invariant all p_{j,k} will be zero when k>j-1. So we split this equation:

d_{i,j} = \sum_{k=1}^{j-1} (p_{i,k} - p_{j,k} )^2 + \sum_{k=j}^{k'} p_{i,j}^2

For the first equation we just get:

d_{i,1} = \sum_{k=1}^{j-1} (p_{i,k} - p_{j,k} )^2 + \sum_{k=j}^{k'} p_i{i,1}^2

This one will need some special treatment later.

Now if we solve all binomials in the normal equation we get:

d_{i,j} = \sum_{k=1}^{j-1} p_{i,k}^2 - 2 p_{i,k} p_{j,k} + p_{j,k}^2 + \sum_{k=j}^{k'} p_{i,j}^2

subtract the first equation from this and you are left with:

d_{i,j} - d_{i,1} = \sum_{k=1}^{j-1} p_{j,k}^2 - 2 p_{i,k} p_{j,k}

for all j > 1.

If you look at this you'll note that all squares of coordinates of p_i are gone and the only squares we need are already known. This is a set of linear equations that can easily be solved using methods from linear algebra. Actually there is one more special thing about this set of equations: The equations already are in triangular form, so you only need the final step of propagating the solutions. For the final step we are left with one single quadratic equation that we can just solve by taking one square root.

I hope you can follow my reasoning. It's a bit late and my head is a bit spinning from those indexes.

EDIT: Yes, there were indexing mistakes. Fixed. I'll try to implement this in python when I have time in order to test it.

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One additional note: It might actually not be necessary to use the full R^{N-1}, for example if three points are on a line four points on a plane etc. In this case there will be a division by zero in the algorithm above. This can be easily accounted for, by detecting when a newly calculated coordinate will be set to zero in the first calculation. In this case you can just skip this point for the rest of the calculation and reduce the number of dimensions of the final point set. –  LiKao Sep 30 '11 at 7:59
Ok, I was wrong for my last comment. As exemplified by the comment to the original question, this problem might not have a solution. That means that algorithm only can find the answer in some cases when the answer exists. I'll be looking for a proof, that it finds the answer in all such cases, but have not yet found one. –  LiKao Sep 30 '11 at 15:49
the complexity of this algorithm is O(n^4), I doubt if it is going to be better than MDS. –  user677656 Mar 8 '12 at 23:16
@g24l: How did you arrive at O(n^4)? The code in the inner loop takes O(1), thus the whole loop will take O( j ), second level than takes O( i^2 ) and finally the full algorithm takes O( n^3 ) not O( n^4). Also MDS takes O( n^2 ) for each iteration with an unknown number of iterations until convergence (possible infinite time). So unless you can be sure that n iterations will be enough to converge this algorithm is better, because it has a guarantee. –  LiKao Mar 9 '12 at 11:03
You result in n^2 equations that will require at least O((n^2)^2) operations to solve at each step. Thus your complexityis O(n^3)+O(Kn^4) where K is the number of iterations for convergence. Moreover, the linear system at the end should be sensitive. –  user677656 Mar 9 '12 at 11:59

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