Bellman-Ford Shortest-Path Algorithm: Difference between revisions

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(Created page with "=Internal= * Shortest Path in a Graph =Overview= An algorithm that can compute shortest path in graphs with negative leng...")
 
 
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=External=
* https://www.coursera.org/learn/algorithms-npcomplete/lecture/x0YZd/single-source-shortest-paths-revisted
* https://www.coursera.org/learn/algorithms-npcomplete/lecture/g8N36/optimal-substructure
* https://www.coursera.org/learn/algorithms-npcomplete/lecture/9YeyY/the-basic-algorithm-i
* https://www.coursera.org/learn/algorithms-npcomplete/lecture/WhILJ/the-basic-algorithm-ii
* https://www.coursera.org/learn/algorithms-npcomplete/lecture/AB5wH/detecting-negative-cycles
* https://www.coursera.org/learn/algorithms-npcomplete/lecture/TrNPq/a-space-optimization
=Internal=
=Internal=
* [[Shortest_Path_in_a_Graph#Shortest_Path_Algorithms|Shortest Path in a Graph]]
* [[Shortest_Path_in_a_Graph#Shortest_Path_Algorithms|Shortest Path in a Graph]]
* [[Dynamic_Programming#Canonical_Use|Dynamic Programming]]
* [[Floyd-Warshall Algorithm]]
* [[Johnson's Algorithm]]
=Overview=
=Overview=
An algorithm that can compute shortest path in graphs with negative length edges.
A dynamic programming algorithm that can compute shortest path in graphs with [[Graph_Concepts#Negative_Length_Edge|negative length edges]].
 
There are n<sup>2</sup> subproblems, and we might spend more than linear time for each subproblem: we have to do brute force search through a list of candidates that might be super-constant: each arc that comes into the vertex v provides a candidate for what the correct solution to the subproblem may be, and the number of candidates is proportional to the degree of vertex v. The running time is O(mn). In a sparse graph, m=O(n), and in a dense graph is O(n<sup>2</sup>).

Latest revision as of 02:44, 30 November 2021

External

Internal

Overview

A dynamic programming algorithm that can compute shortest path in graphs with negative length edges.

There are n2 subproblems, and we might spend more than linear time for each subproblem: we have to do brute force search through a list of candidates that might be super-constant: each arc that comes into the vertex v provides a candidate for what the correct solution to the subproblem may be, and the number of candidates is proportional to the degree of vertex v. The running time is O(mn). In a sparse graph, m=O(n), and in a dense graph is O(n2).