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Line 1: {{Short description\|Method for finding minimum spanning trees}} [[File:Boruvka's algorithm (Sollin's algorithm) Anim.gif\|thumb\|upright=1.35\|Animation of Boruvka's algorithm]]▼ {{Infobox Algorithm ~~{{graph search algorithm}}~~ ▲\|image=[[File:Boruvka's algorithm (Sollin's algorithm) Anim.gif\|~~thumb~~frameless\|upright=1.35~~\|Animation of Boruvka's algorithm~~]] \|caption=Animation of Borůvka's algorithm '''Borůvka's algorithm''' is an [[algorithm]] for finding a [[minimum spanning tree]] in a graph for which all edge weights are distinct,▼ \|class=[[Minimum spanning tree\|Minimum spanning tree algorithm]] \|data=[[Graph (abstract data type)\|Graph]] \|time=<math>O(\|E\|\log \|V\|)</math> }} ▲'''Borůvka's algorithm''' is ana [[greedy algorithm]] for finding a [[minimum spanning tree]] in a graph ~~for which all edge weights are distinct~~, or a minimum spanning forest in the case of a graph that is not connected. It was first published in 1926 by [[Otakar Borůvka]] as a method of constructing an efficient [[electricity network]] for [[Moravia]].<ref>{{cite journal \| last = Borůvka \| first = Otakar \| ~~authorlink~~author-link = Otakar Borůvka \| year = 1926 \| title = O jistém problému minimálním \|trans-title=About a certain minimal problem \| journal = Práce ~~mor~~Mor. ~~přírodověd~~Přírodověd. ~~spol~~Spol. vV Brně III \| volume = 3 \| pages = 37–58 \| url = https://dml.cz/handle/10338.dmlcz/500114 \| language = ~~Czech~~cs, ~~German~~de}}</ref><ref>{{cite journal \| last = Borůvka \| first = Otakar \| ~~authorlink~~author-link = Otakar Borůvka \| year = 1926 \| title = Příspěvek k řešení otázky ekonomické stavby elektrovodních sítí (Contribution to the solution of a problem of economical construction of electrical networks) \| journal = Elektronický Obzor \| volume = 15 \| pages = 153–154 \| language = ~~Czech~~cs }}</ref><ref>{{cite journal \| last1 = Nešetřil \| first1 = Jaroslav \| author1-link = Jaroslav Nešetřil \| last2 = Milková \| first2 = Eva Line 16 ⟶ 21: \| title = Otakar Borůvka on minimum spanning tree problem: translation of both the 1926 papers, comments, history \| volume = 233 \| year = 2001~~}}<~~\| hdl = 10338.dmlcz/~~ref>~~500413 \| hdl-access = free The algorithm was rediscovered by [[Gustave Choquet\|Choquet]] in 1938;<ref>{{cite journal \| last = Choquet \| first = Gustave \| authorlink = Gustave Choquet \| year = 1938 \| title = Étude de certains réseaux de routes \| journal = Comptes Rendus de l'Académie des Sciences \| volume = 206 \| pages = 310–313 \| language = French }}</ref> again by [[Kazimierz Florek\|Florek]], [[Jan Łukasiewicz\|Łukasiewicz]], [[Julian Perkal\|Perkal]], [[Hugo Steinhaus\|Steinhaus]], and [[Stefan Zubrzycki\|Zubrzycki]] in 1951;<ref>{{cite journal▼ }}</ref> ▲The algorithm was rediscovered by [[Gustave Choquet\|Choquet]] in 1938;<ref>{{cite journal \| last = Choquet \| first = Gustave \| ~~authorlink~~author-link = Gustave Choquet \| year = 1938 \| title = Étude de certains réseaux de routes \| journal = Comptes Rendus de l'Académie des Sciences \| volume = 206 \| pages = 310–313 \| language = ~~French~~fr }}</ref> again by [[Kazimierz Florek\|Florek]], [[Jan Łukasiewicz\|Łukasiewicz]], [[Julian Perkal\|Perkal]], [[Hugo Steinhaus\|Steinhaus]], and [[Stefan Zubrzycki\|Zubrzycki]] in 1951;<ref>{{cite journal \| last1 = Florek \| first1 = K. \| last2 = Łukaszewicz \| first2 = J. \| author2-link = Jan Łukasiewicz Line 23 ⟶ 30: \| last4 = Steinhaus \| first4 = Hugo \| author4-link = Hugo Steinhaus \| last5 = Zubrzycki \| first5 = S. \| journal = Colloquium ~~Mathematicae~~Mathematicum \| language = ~~French~~fr \| mr = 0048832 \| pages = 282–285 Line 30 ⟶ 37: \| url = https://eudml.org/doc/209969 \| volume = 2 \| year = 1951\| issue = 3–4 \| year = 1951}}</ref> and again by Georges Sollin in 1965.<ref>{{cite journal \| last = Sollin \| first = Georges \| year = 1965 \| title = Le tracé de canalisation \| journal = Programming, Games, and Transportation Networks \| language = French }}</ref> This algorithm is frequently called '''Sollin's algorithm''', especially in the [[parallel computing]] literature.▼ \| doi = 10.4064/cm-2-3-4-282-285 ▲ ~~\| year = 1951~~}}</ref> and again by Georges Sollin in 1965.<ref>{{cite journal \| last = Sollin \| first = Georges \| year = 1965 \| title = Le tracé de canalisation \| journal = Programming, Games, and Transportation Networks \| language = ~~French~~fr }}</ref> This algorithm is frequently called '''Sollin's algorithm''', especially in the [[parallel computing]] literature. The algorithm begins by finding the minimum-weight edge incident to each vertex of the graph, and adding all of those edges to the forest. Line 38 ⟶ 47: == Pseudocode == ~~Designating each vertex or set of connected vertices a "[[connected component (graph theory)\|component]]", pseudocode for Borůvka's algorithm is:~~ ~~Input: A graph ''G'' whose edges have distinct weights~~ ~~Initialize a forest ''F'' to be a set of one-vertex trees, one for each vertex of the graph.~~ ~~While ''F'' has more than one component:~~ Find the connected components of ''F'' and label each vertex of ''G'' by its component▼ Initialize the cheapest edge for each component to "None"▼ ~~For each edge ''uv'' of ''G'':~~ ~~If ''u'' and ''v'' have different component labels:~~ If ''uv'' is cheaper than the cheapest edge for the component of ''u'':▼ Set ''uv'' as the cheapest edge for the component of ''u''▼ If ''uv'' is cheaper than the cheapest edge for the component of ''v'':▼ Set ''uv'' as the cheapest edge for the component of ''v''▼ For each component whose cheapest edge is not "None":▼ Add its cheapest edge to ''F''▼ Output: ''F'' is the minimum spanning forest of ''G''.▼ The following pseudocode illustrates a basic implementation of Borůvka's algorithm. If edges do not have distinct weights, then a consistent tie-breaking rule (e.g. breaking ties by the object identifiers of the edges) can be used.▼ In the conditional clauses, every edge ''uv'' is considered cheaper than "None". The purpose of the ''completed'' variable is to determine whether the forest ''F'' is yet a spanning forest. An optimization (not necessary for the analysis) is to remove from ''G'' each edge that is found to connect two vertices in the same component as each other.▼ ▲If edges do not have distinct weights, then a consistent '''tie-breaking rule''' must be used, (e.g. ~~breaking~~based ~~ties~~on bysome ~~the~~[[total ~~object~~order]] ~~identifiers~~on ofvertices ~~the~~or edges~~) can be used~~. This can be achieved by representing vertices as integers and comparing them directly; comparing their [[memory address]]es; etc. A tie-breaking rule is necessary to ensure that the created graph is indeed a forest, that is, it does not contain cycles. For example, consider a triangle graph with nodes {''a'',''b'',''c''} and all edges of weight 1. Then a cycle could be created if we select ''ab'' as the minimal weight edge for {''a''}, ''bc'' for {''b''}, and ''ca'' for {''c''}. A tie-breaking rule which orders edges first by source, then by destination, will prevent creation of a cycle, resulting in the minimal spanning tree {''ab'', ''bc''}. '''algorithm''' Borůvka '''is''' '''input:''' A weighted undirected graph ''G'' = (''V'', ''E''). ▲ ~~Output~~ '''output:''' ''F'', ~~is the~~a minimum spanning forest of ''G''. Initialize a forest ''F'' to (''V'', ''{{prime\|E}}'') where ''{{prime\|E}}'' = {}. ''completed'' := '''false''' '''while''' not ''completed'' '''do''' ▲ Find the [[Component_(graph_theory)\|connected ~~components~~component]]s of ''F'' and ~~label~~assign to each vertex ~~of ''G'' by~~ its component ▲ Initialize the cheapest edge for each component to "None" '''for each''' edge ''uv'' in ''E'', where ''u'' and ''v'' are in different components of ''F'': ▲ If let ''uvwx'' ~~is cheaper than~~be the cheapest edge for the component of ''u'': '''if''' is-preferred-over(''uv'', ''wx'') '''then''' ▲ Set ''uv'' as the cheapest edge for the component of ''u'' ▲ If let ''uvyz'' ~~is cheaper than~~be the cheapest edge for the component of ''v'': '''if''' is-preferred-over(''uv'', ''yz'') '''then''' ▲ Set ''uv'' as the cheapest edge for the component of ''v'' '''if''' all components have cheapest edge set to "None" '''then''' ''// no more trees can be merged -- we are finished'' ''completed'' := '''true''' '''else''' ''completed'' := '''false''' ▲ ~~For~~ '''for each''' component whose cheapest edge is not "None": '''do''' ▲ Add its cheapest edge to ''FE''' '''function''' is-preferred-over(''edge1'', ''edge2'') '''is''' '''return''' (''edge2'' is "None") or (weight(''edge1'') < weight(''edge2'')) or (weight(''edge1'') = weight(''edge2'') and tie-breaking-rule(''edge1'', ''edge2'')) '''function''' tie-breaking-rule(''edge1'', ''edge2'') '''is''' The tie-breaking rule; returns '''true''' if and only if ''edge1'' is preferred over ''edge2'' in the case of a tie. ▲AnAs an optimization, ~~(not~~one ~~necessary for the analysis) is to~~could remove from ''G'' each edge that is found to connect two vertices in the same component, asso ~~each~~that it does not contribute to the time for searching for cheapest edges in later ~~other~~components. == Complexity == Borůvka's algorithm can be shown to take {{math\|[[Big O notation\|O]](log ''V'')}} iterations of the outer loop until it terminates, and therefore to run in time {{math\|[[Big O notation\|O]](''E'' log ''V'')}}, where ''{{mvar\|E''}} is the number of edges, and ''{{mvar\|V''}} is the number of vertices in {{mvar\|G}} (assuming {{math\|''GE'' ≥ ''V''}}). In [[planar graph]]s, and more generally in families of graphs closed under [[graph minor]] operations, it can be made to run in linear time, by removing all but the cheapest edge between each pair of components after each stage of the algorithm.<ref>{{Cite book\|last=Eppstein\|first=David\|~~authorlink~~author-link=David Eppstein\|contribution=Spanning trees and spanners\|title=Handbook of Computational Geometry\|editor1-first=J.-R.\|editor1-last=Sack\|editor1-link=Jörg-Rüdiger Sack\|editor2-first=J.\|editor2-last=Urrutia\|editor2-link= Jorge Urrutia Galicia\|publisher=Elsevier\|year=1999\|pages=425–461~~\|postscript=<!--None-->~~}}; {{Cite journal\|last=Mareš\|first=Martin\|title=Two linear time algorithms for MST on minor closed graph classes\|journal=Archivum ~~mathematicum~~Mathematicum\|volume=40\|year=2004\|issue=3\|pages=315–320\|url=http://www.emis.de/journals/AM/04-3/am1139.pdf~~\|postscript=<!--None-->~~}}.</ref> == Example == {\| ~~border=1 cellspacing=2 cellpadding=5~~ class="wikitable" ! \| Image ! width="100" \| components Line 83 ⟶ 118: == Other algorithms == Other algorithms for this problem include [[Prim's algorithm]] and [[Kruskal's algorithm]]. Fast parallel algorithms can be obtained by combining Prim's algorithm with Borůvka's.<ref>{{cite journal\|last1=Bader\|first1=David A.\|last2=Cong\|first2=Guojing\|title=Fast shared-memory algorithms for computing the minimum spanning forest of sparse graphs\|journal=Journal of Parallel and Distributed Computing\|date=2006\|volume=66\|issue=11\|pages=1366–1378\|doi=10.1016/j.jpdc.2006.06.001\|citeseerx=10.1.1.129.8991\|s2cid=2004627}}</ref> A faster randomized minimum spanning tree algorithm based in part on Borůvka's algorithm due to Karger, Klein, and Tarjan runs in expected {{math\|O(''E'')}} time.<ref>{{cite journal\|last1=Karger\|first1=David R.\|last2=Klein\|first2=Philip N.\|last3=Tarjan\|first3=Robert E.\|title=A randomized linear-time algorithm to find minimum spanning trees\|journal=Journal of the ACM\|date=1995\|volume=42\|issue=2\|pages=321–328\|doi=10.1145/201019.201022\|citeseerx=10.1.1.39.9012\|s2cid=832583}}</ref> The best known (deterministic) minimum spanning tree algorithm by [[Bernard Chazelle]] is also based in part on Borůvka's and runs in {{math\|O(''E'' α(''E'',''V''))}} time, where α is ~~the inverse of~~ the [[Ackermann function#Inverse\|inverse Ackermann function]].<ref>{{Cite journal\|last=Chazelle\|first=Bernard\|title=A minimum spanning tree algorithm with inverse-Ackermann type complexity\|journal=J. ACM\|volume=47\|year=2000\|issue=6\|pages=1028–1047\|url=http://www.cs.princeton.edu/~chazelle/pubs/mst.pdf\|doi=10.1145/355541.355562\|citeseerx=10.1.1.115.2318\|s2cid=6276962}}</ref> These randomized and deterministic algorithms combine steps of Borůvka's algorithm, reducing the number of components that remain to be connected, with steps of a different type that reduce the number of edges between pairs of components. ==Notes== <references/> {{Graph traversal algorithms}} ~~{{DEFAULTSORT:Boruvka's Algorithm}}~~ [[Category:Graph algorithms]] [[Category:Spanning tree]]