# Clustering [assessment] algorithm with distance matrix as an input

Can anyone suggest some clustering algorithm which can work with distance matrix as an input? Or the algorithm which can assess the "goodness" of the clustering also based on the distance matrix?

At this moment I'm using a modification of Kruskal's algorithm (http://en.wikipedia.org/wiki/Kruskal%27s_algorithm) to split data into two clusters. It has a problem though. When the data has no distinct clusters the algorithm will still create two clusters with one cluster containing one element and the other containing all the rest. In this case I would rather have one cluster containing all the elements and another one which is empty.

Are there any algorithms which are capable of doing this type of clustering?

Are there any algorithms which can estimate how well the clustering was done or even better how many clusters are there in the data?

The algorithms should work only with distance(similarity) matrices as an input.

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K-nearest neighbors (en.wikipedia.org/wiki/KNN) is a simple and effective clustering algorithm. With a little tweaking it should give you what you need. –  Amichai May 30 '10 at 16:41
K nearest neighboures - in origin, is classification algorithm ( I don't know how to use it in clustering). One of most famouse is K-means clustering. (en.wikipedia.org/wiki/K-means_clustering) –  Max May 30 '10 at 16:51
As far as I know in the original form I will need the coordinates for this algorithm, which I don't have. How do I tweak it so it works with distance matrices? –  Max May 30 '10 at 16:52
As far as I understand, k-means clustering is a cluster analysis algorithm not a clustering algorithm per se. K-means is a fine way of analyzing the goodness of a cluster. Since the k-means clustering problem is NP-hard and you'd need to use some other algorithm to approximate the ideal k-means cluster. Lloyd's algorithm (en.wikipedia.org/wiki/Lloyd's_algorithm), would not work from a distance matrix since it requires the calculation of cluster centroids (also it only works in finding a predefined number of clusters in your data). –  Amichai May 30 '10 at 17:23

Or the algorithm which can assess the "goodness" of the clustering also based on the distance matrix?

KNN should be useful in assessing the “goodness” of a clustering assignment. Here's how:

Given a distance matrix with each point labeled according to the cluster it belongs to (its “cluster label”):

1. Test the cluster label of each point against the cluster labels implied from k-nearest neighbors classification
2. If the k-nearest neighbors imply an alternative cluster, that classified point lowers the overall “goodness” rating of the cluster
3. Sum up the “goodness rating” contributions from each one of your pixels to get a total “goodness rating” for the whole cluster

Unlike k-means cluster analysis, your algorithm will return information about poorly categorized points. You can use that information to reassign certain points to a new cluster thereby improving the overall "goodness" of your clustering.

Since the algorithm knows nothing about the placement of the centroids of the clusters and hence, nothing about the global cluster density, the only way to insure clusters that are both locally and globally dense would be to run the algorithm for a range of k values and finding an arrangement that maximizes the goodness over the range of k values.

For a significant amount of points, you'll probably need to optimize this algorithm; possibly with a hash-table to keep track of the the nearest points relative to each point. Otherwise this algorithm will take quite awhile to compute.

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If he already has the distance between all points, then KNN shouldn't take too long. The big step in KNN generally is computing the euclidean distance between all the points. –  JSchlather May 30 '10 at 17:34
This might work. Thanks! –  Max May 30 '10 at 20:02

Some approaches that can be used to estimate the number of clusters are:

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`scipy.cluster.hierarchy` runs 3 steps, just like Matlab(TM) clusterdata:

``````Y = scipy.spatial.distance.pdist( pts )  # you have this already
Z = hier.linkage( Y, method )  # N-1
T = hier.fcluster( Z, ncluster, criterion=criterion )
``````

Here `linkage` might be a modified Kruskal, dunno. This SO answer (ahem) uses the above.
As a measure of clustering, radius = rms distance to cluster centre is fast and reasonable, for 2d/3d points.

Tell us about your Npt, ndim, ncluster, hier/flat ? Clustering is a largish area, one size does not fit all.

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