Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have asked a question a few days back on how to find the nearest neighbors for a given vector. My vector is now 21 dimensions and before I proceed further, because I am not from the domain of Machine Learning nor Math, I am beginning to ask myself some fundamental questions:

  • Is Euclidean distance a good metric for finding the nearest neighbors in the first place? If not, what are my options?
  • In addition, how does one go about deciding the right threshold for determining the k-neighbors? Is there some analysis that can be done to figure this value out?
  • Previously, I was suggested to use kd-Trees but the Wikipedia page clearly says that for high-dimensions, kd-Tree is almost equivalent to a brute-force search. In that case, what is the best way to find nearest-neighbors in a million point dataset efficiently?

Can someone please clarify the some (or all) of the above questions?

share|improve this question
    
Try asking on metaoptimize.com –  pajton Apr 22 '11 at 0:13
    
"High dimension" is 20 for some people and some data, 50 or 100 or 1000 for others. Please give numbers if you can, e.g. "I've done dim 21, 1000000 data points, using xx". –  denis Apr 26 '11 at 9:34
    
kD-Tree splits the data in two along one dimension at a time. If you have 20 dimensions and only 1M data points, you get about 1 level of tree - where level means split on every axis. Since there is no real depth, you don't get the benefit of ignoring branches of the tree. It's helpful not to think of it so much as a binary tree, but more like a quad-tree, octtree, etc. even though it's implemented like a binary tree. –  phkahler May 2 '11 at 13:27
add comment

14 Answers

up vote 46 down vote accepted

I currently study such problems -- classification, nearest neighbor searching -- for music information retrieval.

You may be interested in Approximate Nearest Neighbor (ANN) algorithms. The idea is that you allow the algorithm to return sufficiently near neighbors (perhaps not the nearest neighbor); in doing so, you reduce complexity. You mentioned the kd-tree; that is one example. But as you said, kd-tree works poorly in high dimensions. In fact, all current indexing techniques (based on space partitioning) degrade to linear search for sufficiently high dimensions [1][2][3].

Among ANN algorithms proposed recently, perhaps the most popular is Locality-Sensitive Hashing (LSH), which maps a set of points in a high-dimensional space into a set of bins, i.e., a hash table [1][3]. But unlike traditional hashes, a locality-sensitive hash places nearby points into the same bin.

LSH has some huge advantages. First, it is simple. You just compute the hash for all points in your database, then make a hash table from them. To query, just compute the hash of the query point, then retrieve all points in the same bin from the hash table.

Second, there is a rigorous theory that supports its performance. It can be shown that the query time is sublinear in the size of the database, i.e., faster than linear search. How much faster depends upon how much approximation we can tolerate.

Finally, LSH is compatible with any Lp norm for 0 < p <= 2. Therefore, to answer your first question, you can use LSH with the Euclidean distance metric, or you can use it with the Manhattan (L1) distance metric. There are also variants for Hamming distance and cosine similarity.

A decent overview was written by Malcolm Slaney and Michael Casey for IEEE Signal Processing Magazine in 2008 [4].

LSH has been applied seemingly everywhere. You may want to give it a try.


[1] Datar, Indyk, Immorlica, Mirrokni, "Locality-Sensitive Hashing Scheme Based on p-Stable Distributions," 2004.

[2] Weber, Schek, Blott, "A quantitative analysis and performance study for similarity-search methods in high-dimensional spaces," 1998.

[3] Gionis, Indyk, Motwani, "Similarity search in high dimensions via hashing," 1999.

[4] Slaney, Casey, "Locality-sensitive hashing for finding nearest neighbors", 2008.

share|improve this answer
    
@Steve: Thank you for the reply. Do you have some suggestions on an LSH implementation? The only one I saw was the one from MIT. Are there any other packages floating around? –  Legend Apr 24 '11 at 21:01
    
Besides that one, no, I don't know of others. I ended up writing my own in Python for my specific purposes. Essentially, each hash table is implemented as a Python dictionary, d, where d[k] is one bin with key k. d[k] contains the labels of all points whose hash is k. Then, you just need to compute the hash for each point. See Eq. (1) in [4], or Section 3 in [1]. –  Steve Tjoa Apr 24 '11 at 21:13
    
@Steve: Thanks for your help. I will start implementing it now. Do you have any idea on how this methodology performs for large datasets by any chance? –  Legend Apr 24 '11 at 21:47
    
You're welcome. It should work pretty well; in fact, the benefit of LSH is even more apparent for large datasets because of its sublinear complexity. I've done it for over 100,000 elements in a 2048-dimensional space. –  Steve Tjoa Apr 24 '11 at 21:49
1  
@SteveTjoa: Found it hard to visually grasp keywords and embedded formula. As you had a single highlight on LSH already, I supplemented it. With only the best intentions. Feel free to revert, though. It's your answer after all. :) –  Regexident Jun 19 '13 at 8:03
show 9 more comments

I. The Distance Metric

First, the number of features (columns) in a data set is not a factor in selecting a distance metric for use in kNN. There are quite a few published studies directed to precisely this question, and the usual bases for comparison are:

  • the underlying statistical distribution of your data;

  • the relationship among the features that comprise your data (are they independent--i.e., what does the covariance matrix look like); and

  • the coordinate space from which your data was obtained.

If you have no prior knowledge of the distribution(s) from which your data was sampled, at least one (well documented and thorough) study concludes that Euclidean distance is the best choice.

YEuclidean metric used in mega-scale Web Recommendation Engines as well as in current academic research. Distances calculated by Euclidean have intuitive meaning and the computation scales--i.e., Euclidean distance is calculated the same way, whether the two points are in two dimension or in twenty-two dimension space.

It has only failed for me a few times, each of those cases Euclidean distance failed because the underlying (cartesian) coordinate system was a poor choice. And you'll usually recognize this because for instance path lengths (distances) are no longer additive--e.g., when the metric space is a chessboard, Manhattan distance is better than Euclidean, likewise when the metric space is Earth and your distances are trans-continental flights, a distance metric suitable for a polar coordinate system is a good idea (e.g., London to Vienna is is 2.5 hours, Vienna to St. Petersburg is another 3 hrs, more or less in the same direction, yet London to St. Petersburg isn't 5.5 hours, instead, is a little over 3 hrs.)

But apart from those cases in which your data belongs in a non-cartesian coordinate system, the choice of distance metric is usually not material. (See this blog post from a CS student, comparing several distance metrics by examining their effect on kNN classifier--chi square give the best results, but the differences are not large; A more comprehensive study is in the academic paper, Comparative Study of Distance Functions for Nearest Neighbors--Mahalanobis (essentially Euclidean normalized by to account for dimension covariance) was the best in this study.

One important proviso: for distance metric calculations to be meaningful, you must re-scale your data--rarely is it possible to build a kNN model to generate accurate predictions without doing this. For instance, if you are building a kNN model to predict athletic performance, and your expectation variables are height (cm), weight (kg), bodyfat (%), and resting pulse (beats per minute), then a typical data point might look something like this: [ 180.4, 66.1, 11.3, 71 ]. Clearly the distance calculation will be dominated by height, while the contribution by bodyfat % will be almost negligible. Put another way, if instead, the data were reported differently, so that bodyweight was in grams rather than kilograms, then the original value of 86.1, would be 86,100, which would have a large effect on your results, which is exactly what you don't want. Probably the most common scaling technique is subtracting the mean and dividing by the standard deviation (mean and sd refer calculated separately for each column, or feature in that data set; X refers to an individual entry/cell within a data row):

X_new = (X_old - mu) / sigma


II. The Data Structure

If you are concerned about performance of the kd-tree structure, A Voronoi Tessellation is a conceptually simple container but that will drastically improve performance and salces better than kd-Trees.

dat

This is not the most common way to persist kNN training data, though the application of VT for this purpose, as well as the consequent performance advantages, are well-documented (see e.g. this Microsoft Research report). The practical significance of this is that, provided you are using a 'mainstream' language (e.g., in the TIOBE Index) then you ought to find a library to perform VT. I know in Python and R, there are multiple options for each language (e.g., the voronoi package for R available on CRAN)

Using a VT for kNN works like this::

From your data, random select w points--these are your Voronoi centers. A Voronoi cell encapsulates all neighboring points that are nearest to each center. Imagine if you assign a different color to each of Voronoi centers, so that each point assigned to a given center is painted that color. As long as you have a sufficient density, doing this will nicely show the boundaries of each Voronoi center (as the boundary that separates two colors.

How to select the Voronoi Centers? I use two orthogonal guidelines. After random selecting the w points, calculate the VT for your training data. Next check the number of data points assigned to each Voronoi center--these values should be about the same (given uniform point density across your data space). In two dimensions, this would cause a VT with tiles of the same size.That's the first rule, here's the second. Select w by iteration--run your kNN algorithm with w as a variable parameter, and measure performance (time required to return a prediction by querying the VT).

So imagine you have one million data points..... If the points were persisted in an ordinary 2D data structure, or in a kd-tree, you would perform on average a couple million distance calculations for each new data points whose response variable you wish to predict. Of course, those calculations are performed on a single data set. With a V/T, the nearest-neighbor search is performed in two steps one after the other, against two different populations of data--first against the Voronoi centers, then once the nearest center is found, the points inside the cell corresponding to that center are searched to find the actual nearest neighbor (by successive distance calculations) Combined, these two look-ups are much faster than a single brute-force look-up. That's easy to see: for 1M data points, suppose you select 250 Voronoi centers to tesselate your data space. On average, each Voronoi cell will have 4,000 data points. So instead of performing on average 500,000 distance calculations (brute force), you perform far lesss, on average just 125 + 2,000.

III. Calculating the Result (the predicted response variable)

There are two steps to calculating the predicted value from a set of kNN training data. The first is identifying n, or the number of nearest neighbors to use for this calculation. The second is how to weight their contribution to the predicted value.

W/r/t the first component, you can determine the best value of n by solving an optimization problem (very similar to least squares optimization). That's the theory; in practice, most people just use n=3. In any event, it's simple to run your kNN algorithm over a set of test instances (to calculate predicted values) for n=1, n=2, n=3, etc. and plot the error as a function of n. If you just want a plausible value for n to get started, again, just use n = 3.

The second component is how to weight the contribution of each of the neighbors (assuming n > 1).

The simplest weighting technique is just multiplying each neighbor by a weighting coefficient, which is just the 1/(dist * K), or the inverse of the distance from that neighbor to the test instance often multiplied by some empirically derived constant, K. I am not a fan of this technique because it often over-weights the closest neighbors (and concomitantly under-weights the more distant ones); the significance of this is that a given prediction can be almost entirely dependent on a single neighbor, which in turn increases the algorithm's sensitivity to noise.

A must better weighting function, which substantially avoids this limitation is the gaussian function, which in python, looks like this:

def weight_gauss(dist, sig=2.0) :
    return math.e**(-dist**2/(2*sig**2))

To calculate a predicted value using your kNN code, you would identify the n nearest neighbors to the data point whose response variable you wish to predict ('test instance'), then call the weight_gauss function, once for each of the n neighbors, passing in the distance between each neighbor the the test point.This function will return the weight for each neighbor, which is then used as that neighbor's coefficient in the weighted average calculation.

share|improve this answer
    
Great answer! Comprehensive and accurate relative to my experience. –  Ted Dunning Jan 15 '12 at 21:05
add comment

What you are facing is known as the curse of dimentionality. It is sometimes useful to run an algorithm like PCA or ICA to make sure that you really need all 21 dimentions and possibly find a linear transformation which would allow you to use less than 21 with approximately the same result quality.

Update: I encountered them in a book called Biomedical Signal Processing by Rangayyan (I hope I remember it correctly). ICA is not a trivial technique, but it was developed by researchers in Finland and I think Matlab code for it is publicly available for download. PCA is a more widely used technique and I believe you should be able to find its R or other software implementation. PCA is performed by solving linear equations iteratively. I've done it too long ago to remember how. = )

The idea is that you break up your signals into independent eigenvectors (discrete eigenfunctions, really) and their eigenvalues, 21 in your case. Each eigenvalue shows the amount of contribution each eigenfunction provides to each of your measurements. If an eigenvalue is tiny, you can very closely represent the signals without using its corresponding eigenfunction at all, and that's how you get rid of a dimension.

share|improve this answer
    
+1 Thank You. This is a very interesting suggestion and makes perfect sense. As a final request, are you familiar with any hands-on tutorial (either in python or R or some other language) that explains how to do this interactively (I mean explaining step by step the whole process). I have read a few documents since yesterday but most of them seem way out of my understanding. Any suggestions? –  Legend Apr 22 '11 at 16:41
    
I updated my response –  Phonon Apr 23 '11 at 22:42
1  
Nitpicking: ICA is not a dimension reduction algorithm. It does not know how to score the components and should not be used as such. –  Gael Varoquaux May 2 '11 at 5:25
add comment

This article considers the problem of finding nearest neighbours: High-Dimensional Feature Matching: Employing the Concept of Meaningful Nearest Neighbors. I hope, it will be helpful.

share|improve this answer
    
@user502144: +1 Thank You. I will read it now. –  Legend Apr 22 '11 at 16:41
add comment

A lot depends on why you want to know the nearest neighbors. You might look into the mean shift algorithm http://en.wikipedia.org/wiki/Mean-shift if what you really want is to find the modes of your data set.

share|improve this answer
2  
As far as i know Mean-Shift is not suited for clustering high dimensional data. K-Means may be a better choice. –  user502144 Apr 22 '11 at 14:16
add comment

Cosine similarity is a common way to compare high-dimension vectors. Note that since it's a similarity not a distance, you'd want to maximize it not minimize it. You can also use a domain-specific way to compare the data, for example if your data was DNA sequences, you could use a sequence similarity that takes into account probabilities of mutations, etc.

The number of nearest neighbors to use varies depending on the type of data, how much noise there is, etc. There are no general rules, you just have to find what works best for your specific data and problem by trying all values within a range. People have an intuitive understanding that the more data there is, the fewer neighbors you need. In a hypothetical situation where you have all possible data, you only need to look for the single nearest neighbor to classify.

The k Nearest Neighbor method is known to be computationally expensive. It's one of the main reasons people turn to other algorithms like support vector machines.

share|improve this answer
    
This is interesting. Can you elaborate more on how I could utilize SVMs in my case? I thought k-nearest neighbors was more like unsupervised and SVMs are supervised. Please correct me if I am wrong. –  Legend Apr 22 '11 at 16:43
1  
Both methods are supervised, because your training data is annotated with the correct classes. If you only have the feature vectors, and don't know the classes they belong in, then you can't use kNN or SVMs. Unsupervised learning methods are usually referred to as clustering algorithms. They can identify groups of similar data, but they don't tell you what the groups mean. –  Colin Apr 22 '11 at 20:27
    
Thank you for the clarification. You are right. It is indeed a supervised technique. I just did not realize what I called categories were actually classes too :) –  Legend Apr 23 '11 at 2:30
add comment

To answer your questions one by one:

  • No, euclidean distance is a very bad metric in high dimensional space. Basically in high dimensions there is little difference between the nearest and the farthest neighbour
  • A lot of papers/research are there in high dimension data, but most of the stuff requires a lot of mathematical sofistication
  • KD tree is very bad for high dimensional data ... avoid it by all means

Here is a nice paper to get you started in the right direction. "When in Nearest Neighbour meaningful?" by Beyer et all.

I work with text data of dimensions 20K and above. If you want some text related advice, I might be able to help you out.

share|improve this answer
    
+1 I am printing out that paper to read it now. In the mean time, do you have suggestions on how else to figure out nearest neighbors? If both the distance metric and the definition of the neighbor itself is flawed, then how do people generally solve higher dimension problems where they want to do approximate matching based on feature vectors? Any suggestions? –  Legend Apr 22 '11 at 16:47
    
In case of text we use cosine similarity a lot. I am working in text classification myself and find that for high dimensions, SVM with linear kernels seem to be the most effective. –  BiGYaN Apr 23 '11 at 19:37
add comment

I think cosine on tf-idf of boolean features would work well for most problems. That's because its time-proven heuristic used in many search engines like Lucene. Euclidean distance in my experience shows bad results for any text-like data. Selecting different weights and k-examples can be done with training data and brute-force parameter selection.

share|improve this answer
add comment

If you think of a clustering algorithm you want to look for a space-filling-curve. A sfc reduce the 2d complexity to a 1d complexity. A sfc, especially a hilbert curve or a moore curve can be easily extended to 3 or more dimension. It's mostly used in mapping application like google maps. I've succesful applied it to a zipcode search of near by consumers. You want to download my class at phpclasses.org (hilbert-curve). You want to look for Nick's hilbert curve quadtree spatial index blog.

share|improve this answer
add comment

KD Trees work fine for 21 dimensions, if you quit early, after looking at say 5 % of all the points. FLANN does this (and other speedups) to match 128-dim SIFT vectors. (Unfortunately FLANN does only the Euclidean metric, and the fast and solid scipy.spatial.cKDTree does only Lp metrics; these may or may not be adequate for your data.) There is of course a speed-accuracy tradeoff here.

(If you could describe your Ndata, Nquery, data distribution, that might help people to try similar data.)

Added 26 April, run times for cKDTree with cutoff on my old mac ppc, to give a very rough idea of feasibility:

kdstats.py p=2 dim=21 N=1000000 nask=1000 nnear=2 cutoff=1000 eps=0 leafsize=10 clustype=uniformp
14 sec to build KDtree of 1000000 points
kdtree: 1000 queries looked at av 0.1 % of the 1000000 points, 0.31 % of 188315 boxes; better 0.0042 0.014 0.1 %
3.5 sec to query 1000 points
distances to 2 nearest: av 0.131  max 0.253

kdstats.py p=2 dim=21 N=1000000 nask=1000 nnear=2 cutoff=5000 eps=0 leafsize=10 clustype=uniformp
14 sec to build KDtree of 1000000 points
kdtree: 1000 queries looked at av 0.48 % of the 1000000 points, 1.1 % of 188315 boxes; better 0.0071 0.026 0.5 %
15 sec to query 1000 points
distances to 2 nearest: av 0.131  max 0.245
share|improve this answer
add comment

kd-trees indeed won't work very well on high-dimensional data. Because the pruning step no longer helps a lot, as the closest edge - a 1 dimensional deviation - will almost always be smaller than the full-dimensional deviation to the known nearest neighbors.

But furthermore, kd-trees only work well with Lp norms for all I know, and there is the distance concentration effect that makes distance based algorithms degrade with increasing dimensionality.

For further information, you may want to read up on the curse of dimensionality, and the various variants of it (there is more than one side to it!)

I'm not convinced there is a lot use to just blindly approximating Euclidean nearest neighbors e.g. using LSH or random projections. It may be necessary to use a much more fine tuned distance function in the first place!

share|improve this answer
add comment

iDistance is probably the best for exact knn retrieval in high-dimensional data. You can view it as an approximate Voronoi tessalation.

share|improve this answer
add comment

I've experienced the same problem and can say the following.

  1. Euclidean distance is a good distance metric, however it's computationally more expensive than the Manhattan distance, and sometimes yields slightly poorer results, thus, I'd choose the later.

  2. The value of k can be found empirically. You can try different values and check the resulting ROC curves or some other precision/recall measure in order to find an acceptable value.

  3. Both Euclidean and Manhattan distances respect the Triangle inequality, thus you can use them in metric trees. Indeed, KD-trees have their performance severely degraded when the data have more than 10 dimensions (I've experienced that problem myself). I found VP-trees to be a better option.

share|improve this answer
add comment

Another possibility, simpler than creating a kd-tree, is using a neighborhood grid.

I will explain the idea for the 2D case, but is straightforward to create a n-dimensional array for the specific case you asked (and sort it in n passes).

First place all your points into a 2D square matrix. Then you can run a full or partial spatial sort, so points will became ordered inside the matrix.

Points with small Y could move to the top rows of the matrix, and likewise, points with large Y would go to the bottom rows. The same will happen with points with small X coordinates, that should move to the columns on the left. And symmetrically, points with large X value will go to the right columns.

After you did the spatial sort (there are many ways to achieve this, both by serial or parallel algorithms) you can lookup the nearest points of a given point P by just visiting the adjacent cells where point P is actually stored in the neighborhood matrix.

You can read more details for this idea in the following paper (you will find PDF copies of it online): Supermassive Crowd Simulation on GPU based on Emergent Behavior.

The sorting step gives you interesting choices. You can use just the even-odd transposition sort described in the paper, which is very simple to implement (even in CUDA). If you run just one pass of this, it will give you a partial sort, which can be already useful if your matrix is near-sorted. That is, if your points move slowly, it will save you a lot of computation.

If you need a full sort, you can run such even-odd transposition pass several times (as described in the following Wikipedia page):

http://en.wikipedia.org/wiki/Odd%E2%80%93even_sort

Another possibility is to implement the spatial sort alternating X and Y passes and using Shell-sort, to achieve a more efficient full sort:

http://en.wikipedia.org/wiki/Shell_sort

Personally I think it is a wonderful solution (have implemented it myself), but still almost unknown.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.