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I've been searching for an answer for this question for quite a while, so I'm hoping someone can help me. I'm using dbscan from the fpc library in R. For example, I am looking at the USArrests data set and am using dbscan on it as follows:

library(fpc)
ds <- dbscan(USArrests,eps=20)

Choosing eps was merely by trial and error in this case. However I am wondering if there is a function or code available to automate the choice of the best eps/minpts. I know some books recommend producing a plot of the kth sorted distance to its nearest neighbour. That is, the x-axis represents "Points sorted according to distance to kth nearest neighbour" and the y-axis represents the "kth nearest neighbour distance".

This type of plot is useful for helping choose an appropriate value for eps and minpts. I hope I have provided enough information for someone to be help me out. I wanted to post a pic of what I meant however I'm still a newbie so can't post an image just yet.

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2 Answers

up vote 2 down vote accepted

There is no general way of choosing minPts. It depends on what you want to find. A low minPts means it will build more clusters from noise, so don't choose it too small.

For epsilon, there are various aspects. It again boils down to choosing whatever works on this data set and this minPts and this distance function and this normalization. You can try to do a knn distance histogram and choose a "knee" there, but there might be no visible one, or multiple.

OPTICS is a successor to DBSCAN that does not need the epsilon parameter (except for performance reasons with index support, see Wikipedia). It's much nicer, but I believe it is a pain to implement in R, because it needs advanced data structures (ideally, a data index tree for acceleration and an updatable heap for the priority queue), and R is all about matrix operations.

Naively, one can imagine OPTICS as doing all values of Epsilon at the same time, and putting the results in a cluster hierarchy.

The first thing you need to check however - pretty much independent of whatever clustering algorithm you are going to use - is to make sure you have a useful distance function and appropriate data normalization. If your distance degenerates, no clustering algorithm will work.

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I'd be surprised if implementing it in R were dramatically harder than in other languages ("R is all about matrix operations" is really quite wrongheaded--the data.frame, probably the most-used data structure in R, is not a matrix but a list.). For performance reasons, when it does get implemented it'll likely be in Rcpp though. –  Ari B. Friedman Oct 15 '12 at 10:42
    
Oh sorry. It was Matlab where these things were a really big pain apparently. For R, some indexing existing in the "rann" package. But I believe fpc does not use that, and as R does not have a "database query" API, it cannot autoconnect the modules. –  Anony-Mousse Oct 15 '12 at 10:49
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In my experiments, fpc DBSCAN was by a factor of 10x slower than other implementations. Only Weka was even much worse (another 8x slower). –  Anony-Mousse Oct 15 '12 at 10:51
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Performance in R is sensitive to implementation. I'm not denying that the algorithm might be harder, but in practice generic algorithms like this tend to be written as libraries and then accessed (LINPACK, GEOS, etc.)--that avoids duplication of optimization effort across lots of languages. R is designed to be reasonable for applied statistical practitioners, and extensible for programmers. Part of that extensibility means using other libraries and languages where helpful. –  Ari B. Friedman Oct 15 '12 at 11:00
    
That pretty much holds for any language... and yet, R packages seem to be mostly stand-alone and interact rather little. Which sometimes is also good, if you think of the .jar mess many Apache projects bring with them... –  Anony-Mousse Oct 15 '12 at 19:37
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One common and popular way of managing the epsilon parameter of DBSCAN is to compute a k-distance plot of your dataset. Basically, you compute the k-nearest neighbors (k-NN) for each data point to understand what is the density distribution of your data, for different k. the KNN is handy because it is a non-parametric method. Once you choose a minPTS (which strongly depends on your data), you fix k to that value. Then you use as epsilon the k-distance corresponding to the area of the k-distance plot (for your fixed k) with a low slope.

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