Vantage-point tree

A vantage-point tree (or VP tree) is a metric tree that segregates data in a metric space by choosing a position in the space (the "vantage point") and partitioning the data points into two parts: those points that are nearer to the vantage point than a threshold, and those points that are not. By recursively applying this procedure to partition the data into smaller and smaller sets, a tree data structure is created where neighbors in the tree are likely to be neighbors in the space.^[1]

One generalization is called a multi-vantage-point tree, or MVP tree: a data structure for indexing objects from large metric spaces for similarity search queries. It uses more than one point to partition each level.^[2]

History

Peter Yianilos claimed that the vantage-point tree was discovered independently by him (Peter Yianilos) and by Jeffrey Uhlmann.^[1] Yet, Uhlmann published this method before Yianilos in 1991.^[3] Uhlmann called the data structure a metric tree, the name VP-tree was proposed by Yianilos. Vantage-point trees have been generalized to non-metric spaces using Bregman divergences by Nielsen et al.^[4]

This iterative partitioning process is similar to that of a k-d tree, but uses circular (or spherical, hyperspherical, etc.) rather than rectilinear partitions. In 2D Euclidean space, this can be visualized as a series of circles segregating the data.

The vantage-point tree is particularly useful in dividing data in a non-standard metric space into a metric tree.

Understanding a vantage-point tree

The way a vantage-point tree stores data can be represented by a circle.^[5] First, understand that each node of this tree contains an input point and a radius. All the left children of a given node are the points inside the circle and all the right children of a given node are outside of the circle. The tree itself does not need to know any other information about what is being stored. All it needs is the distance function that satisfies the properties of the metric space.^[5] Just imagine a circle with a radius. The left children are all located inside the circle and the right children are located outside the circle.

Searching through a vantage-point tree

A vantage-point tree can be used to find the nearest neighbor of a point $x$ . The search algorithm is recursive. At any given step we are working with a node of the tree that has a vantage point $v$ and a threshold distance $t$ . The point of interest $x$ will be some distance from the vantage point $v$ . If that distance $d$ is less than $t$ then use the algorithm recursively to search the subtree of the node that contains the points closer to the vantage point than the threshold $t$ ; otherwise recurse to the subtree of the node that contains the points that are farther than the vantage point than the threshold $t$ . If the recursive use of the algorithm finds a neighboring point $n$ with distance to $x$ that is less than $| t - d |$ then it cannot help to search the other subtree of this node; the discovered node $n$ is returned. Otherwise, the other subtree also needs to be searched recursively.

Advantages of a vantage-point tree

Instead of inferring multidimensional points for domain before the index being built, we build the index directly based on the distance.^[5] Doing this, avoids pre-processing steps.
Updating a vantage-point tree is relatively easy compared to the fast-map approach. For fast maps, after inserting or deleting data, there will come a time when fast-map will have to rescan itself. That takes up too much time and it is unclear to know when the rescanning will start.
Distance based methods are flexible. It is “able to index objects that are represented as feature vectors of a fixed number of dimensions."^[5]

Implementation examples

References

1 2 Yianilos (1993). "Data structures and algorithms for nearest neighbor search in general metric spaces". Proceedings of the fourth annual ACM-SIAM Symposium on Discrete algorithms. Society for Industrial and Applied Mathematics Philadelphia, PA, USA. pp. 311–321. pny93. Retrieved 2008-08-22.
↑ CiteSeerX — Indexing Large Metric Spaces For Similarity Search Queries
↑ Uhlmann, Jeffrey (1991). "Satisfying General Proximity/Similarity Queries with Metric Trees". Information Processing Letters. 40 (4). doi:10.1016/0020-0190(91)90074-r.
↑ Nielsen, Frank (2009). "Bregman vantage point trees for efficient nearest Neighbor Queries". Proceedings of Multimedia and Exp (ICME). IEEE. pp. 878–881.
1 2 3 4 Fu, Ada Wai-chee; Polly Mei-shuen Chan; Yin-Ling Cheung; Yiu Sang Moon (2000). "Dynamic vp-tree indexing for n-nearest neighbor search given pair-wise distances". The VLDB Journal — The International Journal on Very Large Data Bases. Springer-Verlag New York, Inc. Secaucus, NJ, USA. pp. 154–173. vp. Retrieved 2012-10-02.

External links

Understanding VP Trees

Tree data structures

Search trees (dynamic sets/associative arrays)	2–3 2–3–4 AA (a,b) AVL B B+ B* B^x (Optimal) Binary search Dancing HTree Interval Order statistic (Left-leaning) Red-black Scapegoat Splay T Treap UB Weight-balanced

Heaps	Binary Binomial Fibonacci Leftist Pairing Skew Van Emde Boas

Tries	Ctrie C-trie (compressed ADT) Hash Radix Suffix Ternary search X-fast Y-fast

Spatial data partitioning trees	Ball BK BSP Cartesian Hilbert R k-d (implicit k-d) M Metric MVP Octree Priority R Quad R R+ R* Segment VP X

Other trees	Cover Exponential Fenwick Finger Fractal tree index Fusion Hash calendar iDistance K-ary Left-child right-sibling Link/cut Log-structured merge Merkle PQ Range SPQR Top

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