# Tag Info

## Hot answers tagged kdtree

20

They are actually quite different. They serve similar purpose, and they both are trees, but that is about all they have in common. R-Trees are balanced, kd-trees are not (unless bulk-loaded). This is why R-trees are preferred for changing data, as kd-trees may need to be rebuilt to re-optimize. R-Trees are disk-oriented. They actually organize the data in ...

19

R-trees and kd-trees are based on similar ideas (space partitioning based on axis-aligned regions), but the key differences are: Nodes in kd-trees represent separating planes, whereas nodes in R-trees represent bounding boxes. kd-trees partition the whole of space into regions whereas R-trees only partition the subset of space containing the points of ...

12

The "surface area heuristic" (SAH) is considered the best splitting method for building kd-trees, at least within the raytracing community. The idea is to add the plane so that the surface areas of the two child spaces, weighted by the number of objexts in each child, are equal. A good reference on the subject is Ingo Wald's thesis, in particular chapter ...

10

In the book Algorithms in a Nutshell there is a kd tree implementation in java along with a few variations. All of the code is on oreilly.com and the book itself also walk you through the algorithm so you could build one yourself.

10

Look carefully at the 6th frame of the animation on that page. As the algorithm is going back up the recursion, it is possible that there is a closer point on the other side of the hyperplane that it's on. We've checked one half, but there could be an even closer point on the other half. Well, it turns out we can sometimes make a simplification. If it's ...

9

This book introduction, page 3: Given a set of n points in a d-dimensional space, the kd-tree is constructed recursively as follows. First, one finds a median of the values of the ith coordinates of the points (initially, i = 1). That is, a value M is computed, so that at least 50% of the points have their ith coordinate greater-or-equal to M, ...

9

KD tree stores the trained descriptors in a way that it is really faster to find the most similar descriptor when performing the matching. With OpenCV it is really easy to use kd-tree, I will give you an example for the flann matcher: flann::GenericIndex< cvflann::L2<int> > *tree; // the flann searching tree tree = new flann::GenericIndex< ...

7

cKDTree is a subset of KDTree, presumably implemented in C, so therefore faster. Each of them is a binary trie, each of whose nodes represents an axis-aligned hyperrectangle. Each node specifies an axis and splits the set of points based on whether their coordinate along that axis is greater than or less than a particular value. but KDTree also ...

7

This is called a Voronoi Diagram and there are many excellent algorithms for generating them efficiently. The one I've heard about most is Fortune's algorithm, which runs in time O(n log n), though others algorithms exist for this problem. Hope this helps!

6

Answers are not the place to ask questions, but your question is not a question, but a statement that the kd-tree of CGAL sucks. Reading 1.8mio points of a geological data model, and computing the 50 clostest points for each of these points has the following performance on my Dell Precision, Windows7, 64bit, VC10: reading the points from a file: 10 sec ...

5

The difference (algorithmically) is: in quadtrees, the data reaching a node is split into a fixed (2^d), equal size cells, whereas in kdtrees, the data is split into two regions based on some data analysis (e.g. the median of some coordinate). Quadtrees do not scale well to high dimensions, due to the exponential dependency in the dimension. The data ...

5

It does not really matter where you put them. Preferably, keep your tree balanced. So place as many on the left as needed to keep the optimal balance! If your current search radius touches the median, you will have to check the other part, that's all you need to handle tied objects on the other side. This is usually cheaper than some complex handling of ...

5

Thanks to John Vinyard for suggesting scipy. After some good research and testing, here is the solution to this question: Prerequisites: Install Numpy and SciPy 1)Import the SciPy and Numpy Modules 2)Make a copy of the 5 dimensional array including JUST the X and Y values. 3)Create an instance of a cKDTree as such: ...

5

If your data is always of the form shown I think you should be able to do better than a spatial tree data structure. Since the data is structured in y you should be able to calculate which 'strip' of rectangles the points is in based on offsets in O(1) time. If you store the individual rectangles within each 'strip' in sorted order (using xmax say) you ...

5

It depends a lot on what your usage patterns are (how my writes, for example, in-memory or on-disk) and how your data looks like (that is how it is distributed). R-trees are good because they are balanced, and allow updating. The R*-tree in my experience is clearly better than the other variants because of the split strategy it has. The benefit is that it ...

5

The question is weather you actually want to determine a keypoint matching between two images, or calculate a similarity measure. If you want to determine a matching, then I'm afraid you will have to brute-force search through all possible descriptor pairs between two images (there is some more advanced methods such as FLANN - Fast Approximate Nearest ...

5

The Curse of Dimensionality gets in the way here. You might consider applying Principal Component Analysis (PCA) to reduce the dimensionality, but as far as I know, nobody has a great answer for this. I have dealt with this type of problem before (in audio and video fingerprinting), sometimes with up to 30 dimensions. Analysis usually revealed that some of ...

5

Another data structure that comes to mind is the cover tree. Unlike KD trees which were originally developed to answer range queries, this data structure is optimal for nearest neighbor queries. It has been used in n-body problems that involve computing the k nearest neighbors of all the data points. Such problems also occur in density estimation schemes ...

5

You find the nearest neighbour exactly as described on the Wikipedia page under the heading "Nearest neighbour search". The description there applies in any number of dimensions. That is: Go down the tree recursively from the root as if you're about to insert the point you're looking for the nearest neighbour of. When you reach a leaf, note it as ...

5

Probably one of the hottest blog posts I had read a year or so ago: Levenstein Automata. Take a look at that article. It provides not only a description of the algorithm but also code to follow. Technically, it's not a kd-tree but it's quite related to the string matching and dictionary correction algorithms one might encounter/use in the real world. He ...

5

I'd suggest first understanding slow feature matching, without kdtrees. input: 1000 reference features, e.g. of faces or flowers; call these F1 .. F1000 a query feature Q: which face or flower feature is most like, nearest, Q ? As you know, SIFT reduces an image feature to 128 8-bit numbers, scaled so that   similarity( feature F, feature Q ) = ...

5

There's a GHC extension being worked on called TypeNats, which would be exactly what you want. However the milestone for that is currently set to be 7.4.1 according to the ticket, so that'll be a bit of a wait still. Until that extension is available, the only thing you can do is encode the dimension using types. For example something along these lines ...

5

I've just spend some time puzzling out the Wikipedia description of the algorithm myself, and came up with the following Python implementation that may help: https://gist.github.com/863301 The first phase of closest_point is a simple depth first search to find the best matching leaf node. Instead of simply returning the best node found back up the call ...

5

Depending on your needs, you may want to experiment with approximate techniques. For details, checkout Arya and Mount's work on the subject. A key paper is here. BigO complexity details are located in their '98 paper. I have used their library on very high dimensional datasets with hundreds of thousands of elements. It's faster than anything else I found. ...

4

This code is optimized for SIZE. So you'll see a lot of "bad hacks". Note that we used 'struct', but it can be easily changed to be a class if you add public:. Paste also missing 'Point2D' type but you can guess how it looks. Includes and Include guards also removed. /* ------------------------------ kdtree.h ------------------------------ */ typedef ...

4

Well, it primarily depends on your particular implementation and data set. A poorly balanced tree will mean you have to search way more data than you need to. Make sure that your tree construction is sane. It could also depend on how you find the k neighbors. If your algorithm searches the tree for the closest neighbor and stores it, then searches for ...

4

(1) I think i is a typo; I don't have anything like that in my implementation of it, and it appears to work fine (famous last words..). (2) whichAxis is the plane you're searching for the minimum in. So in two-dimensional data, it'll be either x or y. E.g. for points (20,40) and (40,20), one is the minimum in x and the other in y. When you start searching ...

4

I've had success with Professor Levy's implementation found here. I realize you're looking for a more production-certified implementation so this is probably not a good fit. However note to any passers-by, I've been using it for a while now in my photomosaic project with no issues. No guarantee but better than nothing :)

4

KD-tree does not work well for high-dimensional data, and 128 dimensions would be quite high. The KD-tree indexes each dimension at a different level of the tree, and when performing a query the algorithm will do a lot of back-tracking (searching both sides of a branch) and ends up searching most of the points in the tree. When this happens the advantages of ...

4

It appears to depend on how you construct the tree. The Wikipedia article mentions how the selection of the median point affects whether the generated tree is balanced or not. If a different point is selected, then the tree will not be balanced but will still be a kd-tree. Therefore, the answer to your question depends on exactly how your tree construction ...

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