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{{Short description|Stack-based method for clustering}}
{{good article}}
In the theory of [[cluster analysis]], the '''nearest-neighbor chain algorithm''' is an [[algorithm]] that can speed up several methods for [[agglomerative hierarchical clustering]]. These are methods that take a collection of points as input, and create a hierarchy of clusters of points by repeatedly merging pairs of smaller clusters to form larger clusters. The clustering methods that the nearest-neighbor chain algorithm can be used for include [[Ward's method]], [[complete-linkage clustering]], and [[single-linkage clustering]]; these all work by repeatedly merging the closest two clusters but use different definitions of the distance between clusters. The cluster distances for which the nearest-neighbor chain algorithm works are called ''reducible'' and are characterized by a simple inequality among certain cluster distances.
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==Background==
[[File:Hierarchical clustering diagram.png|thumb|upright=1.35|A hierarchical clustering of six points. The points to be clustered are at the top of the diagram, and the nodes below them represent clusters.]]
Many problems in [[data analysis]] concern [[Cluster analysis|clustering]], grouping data items into clusters of closely related items. [[Hierarchical clustering]] is a version of cluster analysis in which the clusters form a hierarchy or tree-like structure rather than a strict partition of the data items. In some cases, this type of clustering may be performed as a way of performing cluster analysis at multiple different scales simultaneously. In others, the data to be analyzed naturally has an unknown tree structure and the goal is to recover that structure by performing the analysis. Both of these kinds of analysis can be seen, for instance, in the application of hierarchical clustering to [[Taxonomy (biology)|biological taxonomy]]. In this application, different living things are grouped into clusters at different scales or levels of similarity ([[Taxonomic rank|species, genus, family, etc]]). This analysis simultaneously gives a multi-scale grouping of the organisms of the present age, and aims to accurately reconstruct the [[branching process]] or [[Phylogenetic tree|evolutionary tree]] that in past ages produced these organisms.<ref>{{citation
| last = Gordon | first = Allan D.
| editor1-last = Arabie | editor1-first = P.
| editor2-last = Hubert | editor2-first = L. J.
| editor3-last = De Soete | editor3-first = G.
| contribution = Hierarchical clustering
| contribution-url = https://books.google.com/books?id=HbfsCgAAQBAJ&pg=PA65
| isbn = 9789814504539
| ___location = River Edge, NJ
| pages = 65–121
| publisher = World Scientific
| title = Clustering and Classification
| year = 1996}}.</ref>
The input to a clustering problem consists of a set of points.<ref name="murtagh-tcj"/> A ''cluster'' is any proper subset of the points, and a hierarchical clustering is a [[maximal element|maximal]] family of clusters with the property that any two clusters in the family are either nested or [[disjoint set|disjoint]].
Alternatively, a hierarchical clustering may be represented as a [[binary tree]] with the points at its leaves; the clusters of the clustering are the sets of points in subtrees descending from each node of the tree.<ref>{{citation|title=Clustering|volume=10|series=IEEE Press Series on Computational Intelligence|first1=Rui|last1=Xu|first2=Don|last2=Wunsch|publisher=John Wiley & Sons|year=2008|isbn=978-0-470-38278-3|page=31|contribution-url=https://books.google.com/books?id=kYC3YCyl_tkC&pg=PA31|contribution=3.1 Hierarchical Clustering: Introduction}}.</ref>
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The distance or dissimilarity should be symmetric: the distance between two points does not depend on which of them is considered first.
However, unlike the distances in a [[metric space]], it is not required to satisfy the [[triangle inequality]].<ref name="murtagh-tcj"/>
Next, the dissimilarity function is extended from pairs of points to pairs of clusters. Different clustering methods perform this extension in different ways. For instance, in the [[single-linkage clustering]] method, the distance between two clusters is defined to be the minimum distance between any two points from each cluster. Given this distance between clusters, a hierarchical clustering may be defined by a [[greedy algorithm]] that initially places each point in its own single-point cluster and then repeatedly forms a new cluster by merging the [[closest pair]] of clusters.<ref name="murtagh-tcj"/>
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| arxiv = cs.DS/9912014
| issue = 1
| journal =
| pages = 1–23
| publisher = ACM
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| url = http://www.jea.acm.org/2000/EppsteinDynamic/
| volume = 5
| year = 2000| doi = 10.1145/351827.351829 | bibcode = 1999cs.......12014E | s2cid = 1357701 }}.</ref><ref name="day-edels">{{citation
| last1 = Day | first1 = William H. E.
| last2 = Edelsbrunner | first2 = Herbert | author2-link = Herbert Edelsbrunner
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| url = http://www.cs.duke.edu/~edels/Papers/1984-J-05-HierarchicalClustering.pdf
| volume = 1
| year = 1984| s2cid = 121201396
==The algorithm==
[[File:Nearest-neighbor chain algorithm animated.gif|frame
Intuitively, the nearest neighbor chain algorithm repeatedly follows a chain of clusters {{math|''A'' → ''B'' → ''C'' → ...}} where each cluster is the nearest neighbor of the previous one, until reaching a pair of clusters that are mutual nearest neighbors.<ref name="murtagh-tcj">{{citation
| last = Murtagh | first = Fionn
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| year = 1983
| url = http://www.multiresolutions.com/strule/old-articles/Survey_of_hierarchical_clustering_algorithms.pdf
| doi = 10.1093/comjnl/26.4.354| doi-access = free
}}.</ref> In more detail, the algorithm performs the following steps:<ref name="murtagh-tcj"/><ref name="murtagh-hmds">{{citation
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| editor1-last = Abello | editor1-first = James M.
| editor2-last = Pardalos | editor2-first = Panos M.
| editor3-last = Resende | editor3-first = Mauricio G. C. | editor3-link = Mauricio Resende
| contribution = Clustering in massive data sets
| isbn = 978-1-4020-0489-6
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| title = A general theory of classificatory sorting strategies. I. Hierarchical systems
| volume = 9
| year = 1967
}}.</ref>
:<math>d(A\cup B,C) = \frac{n_A+n_C}{n_A+n_B+n_C} d(A,C) + \frac{n_B+n_C}{n_A+n_B+n_C} d(B,C) - \frac{n_C}{n_A+n_B+n_C} d(A,B).</math>
Distance update formulas such as this one are called formulas "of Lance–Williams type" after the work of {{harvtxt|Lance|Williams|1967}}.
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===Centroid distance===
Another distance measure commonly used in agglomerative clustering is the distance between the centroids of pairs of clusters, also known as the weighted group method.<ref name="mirkin"/><ref name="lance-williams"/> It can be calculated easily in constant time per distance calculation. However, it is not reducible. For instance, if the input forms the set of three points of an [[equilateral triangle]], merging two of these points into a larger cluster causes the inter-cluster distance to decrease, a violation of reducibility. Therefore, the nearest-neighbor chain algorithm will not necessarily find the same clustering as the greedy algorithm. Nevertheless, {{harvtxt|Murtagh|1983}} writes that the nearest-neighbor chain algorithm provides "a good [[heuristic]]" for the centroid method.<ref name="murtagh-tcj"/>
A different algorithm by {{harvtxt|Day|Edelsbrunner|1984}} can be used to find the greedy clustering in {{math|''O''(''n''<sup>2</sup>)}} time for this distance measure.<ref name="day-edels"/>
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{{reflist|colwidth=30em}}
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