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Im trying to analyse data from cycle accidents in the UK to find statistical black spots. Here is the example of the data from another website.

I am currently using SQLite to ~100k store lat / lon locations. I want to group nearby locations together. This task is called cluster analysis.

I would like simplify the dataset by ignoring isolated incidents and instead only showing the origin of clusters where more than one accident have taken place in a small area.

There are 3 problems I need to overcome.

  1. Performance - How do I ensure finding nearby points is quick. Should I use SQLite's implementation of an R-Tree for example?

  2. Chains - How do I avoid picking up chains of nearby points?

  3. Density - How to take cycle population density into account? There is a far greater population density of cyclist in london then say Bristol, therefore there appears to be a greater number of backstops in London.

I would like to avoid 'chain' scenarios like this:

enter image description here

Instead I would like to find clusters:

enter image description here

London screenshot (I hand drew some clusters)...

enter image description here

Bristol screenshot - Much lower density - the same program ran over this area might not find any blackspots if relative density was not taken into account.

enter image description here

Any pointers would be great!

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Have you tried to use regular grid to limit number of points to search? Would be easier to implement than R-Tree... – Alexei Levenkov Feb 4 '13 at 20:43
@AlexeiLevenkov Thanks. Does this mean grouping the points by tiles? How do you deal with points overlapping tile boundaries? Do you have too look at adjacent tiles? – Robert Feb 4 '13 at 20:51
Yes - somewhat simplest optimization for such type of search. But finding existing implementation (i.e. as you've mentioned SQLite one) it likely to provide more reliable and faster solution. – Alexei Levenkov Feb 5 '13 at 1:22
Is the data available somewhere? It's interesting. – Anony-Mousse Feb 5 '13 at 12:58
Yes - Took me ages to find it initially... The UK government publishes a huge amount of data. It;s really quite cool! – Robert Feb 5 '13 at 13:06
up vote 8 down vote accepted

Well, your problem description reads exactly like the DBSCAN clustering algorithm (Wikipedia). It avoids chain effects in the sense that it requires them to be at least minPts objects.

As for the differences in densities across, that is what OPTICS (Wikipedia) is supposed do solve. You may need to use a different way of extracting clusters though.

Well, ok, maybe not 100% - you maybe want to have single hotspots, not areas that are "density connected". When thinking of an OPTICS plot, I figure you are only interested in small but deep valleys, not in large valleys. You could probably use the OPTICS plot an scan for local minima of "at least 10 accidents".

Update: Thanks for the pointer to the data set. It's really interesting. So I did not filter it down to cyclists, but right now I'm using all 1.2 million records with coordinates. I've fed them into ELKI for analysis, because it's really fast, and it actually can use the geodetic distance (i.e. on latitude and longitude) instead of Euclidean distance, to avoid bias. I've enabled the R*-tree index with STR bulk loading, because that is supposed to help to get the runtime down a lot. I'm running OPTICS with Xi=.1, epsilon=1 (km) and minPts=100 (looking for large clusters only). Runtime was around 11 Minutes, not too bad. The OPTICS plot of course would be 1.2 million pixels wide, so it's not really good for full visualization anymore. Given the huge threshold, it identified 18 clusters with 100-200 instances each. I'll try to visualize these clusters next. But definitely try a lower minPts for your experiments.

So here are the major clusters found:

  • 51.690713 -0.045545 a crossing on A10 north of London just past M25
  • 51.477804 -0.404462 "Waggoners Roundabout"
  • 51.690713 -0.045545 "Halton Cross Roundabout" or the crossing south of it
  • 51.436707 -0.499702 Fork of A30 and A308 Staines By-Pass
  • 53.556186 -2.489059 M61 exit to A58, North-West of Manchester
  • 55.170139 -1.532917 A189, North Seaton Roundabout
  • 55.067229 -1.577334 A189 and A19, just south of this, a four lane roundabout.
  • 51.570594 -0.096159 Manour House, Picadilly Line
  • 53.477601 -1.152863 M18 and A1(M)
  • 53.091369 -0.789684 A1, A17 and A46, a complex construct with roundabouts on both sides of A1.
  • 52.949281 -0.97896 A52 and A46
  • 50.659544 -1.15251 Isle of Wight, Sandown.
  • ...

Note, these are just random points taken from the clusters. It may be sensible to compute e.g. cluster center and radius instead, but I didn't do that. I just wanted to get a glimpse of that data set, and it looks interesting.

Here are some screenshots, with minPts=50, epsilon=0.1, xi=0.02:

Some clusters in central London

Notice that with OPTICS, clusters can be hierarchical. Here is a detail:

Nested clusters - OPTICS produces a hierarchy

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Really cool answer! Im going to look though this all tonight! Thank you :) – Robert Feb 5 '13 at 13:09

First, your example is quite misleading. You have two different sets of data, and you don't control the data. If it appears in a chain, then you will get a chain out.

This problem is not exactly suitable for a database. You'll have to write code or find a package that implements this algorithm on your platform.

There are many different clustering algorithms. One, k-means, is an iterative algorithm where you look for a fixed number of clusters. k-means requires a few complete scans of the data, and voila, you have your clusters. Indexes are not particularly helpful.

Another, which is usually appropriate on slightly smaller data sets, is hierarchical clustering -- you put the two closest things together, and then build the clusters. An index might be helpful here.

I recommend though that you peruse a site such as kdnuggets in order to see what software -- free and otherwise -- is available.

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