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Shortest Paths and Minimum Spanning Trees

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1 Shortest Paths and Minimum Spanning Trees
David Kauchak cs302 Spring 2013

2 Admin Can resubmit homeworks 12-15 for up to half credit back
Due by the end of the week Read book

3 3 B D 3 1 2 A 1 1 C E 4

4 3 B D 3 1 2 A 1 1 C E 4

5 Heap A 0 B  C  D  E  3 B D 3 1 2 A 1 1 C E 4

6 Heap B  C  D  E  3 B D 3 1 2 A 1 1 C E 4

7 Heap B  C  D  E  3 B D 3 1 2 A 1 1 C E 4

8 Heap C 1 B  D  E  3 B D 3 1 2 A 1 1 1 C E 4

9 Heap C 1 B  D  E  3 B D 3 1 2 A 1 1 1 C E 4

10 Heap C 1 B 3 D  E  3 3 B D 3 1 2 A 1 1 1 C E 4

11 Heap C 1 B 3 D  E  3 3 B D 3 1 2 A 1 1 1 C E 4

12 Heap B 3 D  E  3 3 B D 3 1 2 A 1 1 1 C E 4

13 Heap B 3 D  E  3 3 B D 3 1 2 A 1 1 1 C E 4

14 Heap B 3 D  E  3 3 B D 3 1 2 A 1 1 1 C E 4

15 Heap B 2 D  E  2 3 B D 3 1 2 A 1 1 1 C E 4

16 Heap B 2 D  E  2 3 B D 3 1 2 A 1 1 1 C E 4

17 Heap B 2 E 5 D  2 3 B D 3 1 2 A 1 1 1 C E 5 4

18 Heap E 3 D 5 2 5 3 B D 3 1 2 A 1 1 1 C E 3 4

19 Heap D 5 2 5 3 B D 3 1 2 A 1 1 1 C E 3 4

20 Heap 2 5 3 B D 3 1 2 A 1 1 1 C E 3 4

21 Heap 2 5 3 B D 1 A 1 1 1 C E 3

22 Is Dijkstra’s algorithm correct?
Invariant:

23 Is Dijkstra’s algorithm correct?
Invariant: For every vertex removed from the heap, dist[v] is the actual shortest distance from s to v proof?

24 Is Dijkstra’s algorithm correct?
Invariant: For every vertex removed from the heap, dist[v] is the actual shortest distance from s to v The only time a vertex gets visited is when the distance from s to that vertex is smaller than the distance to any remaining vertex Therefore, there cannot be any other path that hasn’t been visited already that would result in a shorter path

25 Running time?

26 Running time? 1 call to MakeHeap

27 Running time? |V| iterations

28 Running time? |V| calls

29 Running time? O(|E|) calls

30 Running time? Depends on the heap implementation 1 MakeHeap
|V| ExtractMin |E| DecreaseKey Total Array O(|V|) O(|V|2) O(|E|) O(|V|2) Bin heap O(|V|) O(|V| log |V|) O(|E| log |V|) O((|V|+|E|) log |V|) O(|E| log |V|)

31 Running time? Depends on the heap implementation
1 MakeHeap |V| ExtractMin |E| DecreaseKey Total Array O(|V|) O(|V|2) O(|E|) O(|V|2) Bin heap O(|V|) O(|V| log |V|) O(|E| log |V|) O((|V|+|E|) log |V|) O(|E| log |V|) Is this an improvement? If |E| < |V|2 / log |V|

32 Running time? Depends on the heap implementation 1 MakeHeap
|V| ExtractMin |E| DecreaseKey Total Array O(|V|) O(|V|2) O(|E|) O(|V|2) Bin heap O(|V|) O(|V| log |V|) O(|E| log |V|) O((|V|+|E|) log |V|) O(|E| log |V|) Fib heap O(|V|) O(|V| log |V|) O(|E|) O(|V| log |V| + |E|)

33 What about Dijkstra’s on…?
1 B D 1 5 A 10 -10 E C

34 What about Dijkstra’s on…?
Dijkstra’s algorithm only works for positive edge weights 1 B D 1 5 A 10 E C

35 Bounding the distance Another invariant: For each vertex v, dist[v] is an upper bound on the actual shortest distance Is this a valid invariant?

36 Bounding the distance Another invariant: For each vertex v, dist[v] is an upper bound on the actual shortest distance start off at  only update the value if we find a shorter distance An update procedure

37 Can we ever go wrong applying this update rule?
We can apply this rule as many times as we want and will never underestimate dist[v] When will dist[v] be right? If u is along the shortest path to v and dist[u] is correct

38 Consider the shortest path from s to v
dist[v] will be right if u is along the shortest path to v and dist[u] is correct Consider the shortest path from s to v s p1 p2 p3 pk v

39 What happens if we update all of the vertices with the above update?
dist[v] will be right if u is along the shortest path to v and dist[u] is correct What happens if we update all of the vertices with the above update? s p1 p2 p3 pk v

40 What happens if we update all of the vertices with the above update?
dist[v] will be right if u is along the shortest path to v and dist[u] is correct What happens if we update all of the vertices with the above update? s p1 p2 p3 pk v correct

41 What happens if we update all of the vertices with the above update?
dist[v] will be right if u is along the shortest path to v and dist[u] is correct What happens if we update all of the vertices with the above update? s p1 p2 p3 pk v correct correct

42 Does the order that we update the vertices matter?
dist[v] will be right if u is along the shortest path to v and dist[u] is correct Does the order that we update the vertices matter? yes! If we did it in the order of the correct path, we’d be done. s p1 p2 p3 pk v correct correct

43 dist[v] will be right if u is along the shortest path to v and dist[u] is correct
How many times do we have to do this for vertex pi to have the correct shortest path from s? i times s p1 p2 p3 pk v

44 dist[v] will be right if u is along the shortest path to v and dist[u] is correct
How many times do we have to do this for vertex pi to have the correct shortest path from s? i times s p1 p2 p3 pk v correct correct

45 dist[v] will be right if u is along the shortest path to v and dist[u] is correct
How many times do we have to do this for vertex pi to have the correct shortest path from s? i times s p1 p2 p3 pk v correct correct correct

46 dist[v] will be right if u is along the shortest path to v and dist[u] is correct
How many times do we have to do this for vertex pi to have the correct shortest path from s? i times s p1 p2 p3 pk v correct correct correct correct

47 dist[v] will be right if u is along the shortest path to v and dist[u] is correct
How many times do we have to do this for vertex pi to have the correct shortest path from s? i times s p1 p2 p3 pk v correct correct correct correct

48 dist[v] will be right if u is along the shortest path to v and dist[u] is correct
What is the longest (vertex-wise) the path from s to any node v can be? |V| - 1 edges/vertices s p1 p2 p3 pk v correct correct correct correct

49 Bellman-Ford algorithm

50 Bellman-Ford algorithm
Initialize all the distances do it |V| -1 times iterate over all edges/vertices and apply update rule

51 Bellman-Ford algorithm
check for negative cycles

52 Negative cycles What is the shortest path from a to e? B D A E C 1 1 5
10 -10 E C 3

53 Bellman-Ford algorithm

54 Bellman-Ford algorithm
10 How many edges is the shortest path from s to: S A 8 1 -4 B G A: 2 1 1 -2 C F 3 -1 E D -1

55 Bellman-Ford algorithm
10 How many edges is the shortest path from s to: S A 8 1 -4 B G A: 3 2 1 1 -2 C F 3 -1 E D -1

56 Bellman-Ford algorithm
10 How many edges is the shortest path from s to: S A 8 1 -4 B G A: 3 2 1 1 B: -2 C F 3 -1 E D -1

57 Bellman-Ford algorithm
10 How many edges is the shortest path from s to: S A 8 1 -4 B G A: 3 2 1 1 B: 5 -2 C F 3 -1 E D -1

58 Bellman-Ford algorithm
10 How many edges is the shortest path from s to: S A 8 1 -4 B G A: 3 2 1 1 B: 5 -2 C F 3 -1 D: E D -1

59 Bellman-Ford algorithm
10 How many edges is the shortest path from s to: S A 8 1 -4 B G A: 3 2 1 1 B: 5 -2 C F 3 -1 D: 7 E D -1

60 Bellman-Ford algorithm
10 S A Iteration: 0 8 1 -4 B G 2 1 1 -2 C F 3 -1 E D -1

61 Bellman-Ford algorithm
10 10 S A Iteration: 1 8 1 -4 B 8 G 2 1 1 -2 C F 3 -1 E D -1

62 Bellman-Ford algorithm
10 10 S A Iteration: 2 8 1 -4 B 8 G 2 1 1 -2 C F 9 3 -1 E D -1 12

63 Bellman-Ford algorithm
5 10 S A Iteration: 3 8 1 10 -4 B A has the correct distance and path 8 G 2 1 1 -2 C F 9 3 -1 E D -1 8

64 Bellman-Ford algorithm
5 10 S A Iteration: 4 8 1 6 -4 B 8 G 2 1 1 -2 C 11 F 9 3 -1 E D -1 7

65 Bellman-Ford algorithm
5 10 S A Iteration: 5 8 1 5 -4 B B has the correct distance and path 8 G 2 1 1 -2 C 7 F 9 3 -1 E D -1 14 7

66 Bellman-Ford algorithm
5 10 S A Iteration: 6 8 1 5 -4 B 8 G 2 1 1 -2 C 6 F 9 3 -1 E D -1 10 7

67 Bellman-Ford algorithm
5 10 S A Iteration: 7 8 1 5 -4 B D (and all other nodes) have the correct distance and path 8 G 2 1 1 -2 C 6 F 9 3 -1 E D -1 9 7

68 Correctness of Bellman-Ford
Loop invariant:

69 Correctness of Bellman-Ford
Loop invariant: After iteration i, all vertices with shortest paths from s of length i edges or less have correct distances

70 Runtime of Bellman-Ford
O(|V| |E|)

71 Runtime of Bellman-Ford
Can you modify the algorithm to run faster (in some circumstances)?

72 Single source shortest paths
All of the shortest path algorithms we’ve looked at today are call “single source shortest paths” algorithms Why?

73 All pairs shortest paths
Simple approach Call Bellman-Ford |V| times O(|V|2 |E|) Floyd-Warshall – Θ(|V|3) Johnson’s algorithm – O(|V|2 log |V| + |V| |E|)

74 Minimum spanning trees
What is the lowest weight set of edges that connects all vertices of an undirected graph with positive weights Input: An undirected, positive weight graph, G=(V,E) Output: A tree T=(V,E’) where E’  E that minimizes

75 MST example 1 A C E 3 4 4 2 5 4 B D F 4 6 1 A C E 4 2 5 4 B D F

76 MSTs Can an MST have a cycle? 1 A C E 4 2 5 4 B D F 4

77 MSTs Can an MST have a cycle? 1 A C E 4 2 5 4 B D F

78 Applications? Connectivity
Networks (e.g. communications) Circuit design/wiring hub/spoke models (e.g. flights, transportation) Traveling salesman problem? MST is a lower bound on TSP. 2 * MST is one approximate solution to the TSP problem.

79 Algorithm ideas? 1 A C E 3 4 4 2 5 4 B D F 4 6 1 A C E 4 2 5 4 B D F

80 Cuts A cut is a partitioning of the vertices into two sets S and V-S
An edge “crosses” the cut if it connects a vertex uV and vV-S 1 A C E 3 4 4 2 5 4 B D F 4 6

81 Minimum cut property Prove this!
Given a partion S, let edge e be the minimum cost edge that crosses the partition. Every minimum spanning tree contains edge e. Prove this! 1 A C E 3 4 4 2 5 4 B D F 4 6

82 Minimum cut property Given a partion S, let edge e be the minimum cost edge that crosses the partition. Every minimum spanning tree contains edge e. S V-S e e’ Consider an MST with edge e’ that is not the minimum edge

83 Minimum cut property Given a partion S, let edge e be the minimum cost edge that crosses the partition. Every minimum spanning tree contains edge e. S V-S e e’ Using e instead of e’, still connects the graph, but produces a tree with smaller weights

84 Kruskal’s algorithm Given a partition S, let edge e be the minimum cost edge that crosses the partition. Every minimum spanning tree contains edge e.

85 MST G Kruskal’s algorithm
Add smallest edge that connects two sets not already connected 1 A C E 3 4 5 4 2 4 MST B D F 4 6 A C E G B D F

86 MST G Kruskal’s algorithm
Add smallest edge that connects two sets not already connected 1 A C E 3 4 5 4 2 4 MST B D F 1 4 6 A C E G B D F

87 MST G Kruskal’s algorithm
Add smallest edge that connects two sets not already connected 1 A C E 3 4 5 4 2 4 MST B D F 1 4 6 A C E G 2 B D F

88 MST G Kruskal’s algorithm
Add smallest edge that connects two sets not already connected 1 A C E 3 4 5 4 2 4 MST B D F 1 4 6 A C E G 2 4 B D F

89 MST G Kruskal’s algorithm
Add smallest edge that connects two sets not already connected 1 A C E 3 4 4 2 5 4 MST B D F 1 4 6 A C E G 4 2 4 B D F

90 MST G Kruskal’s algorithm
Add smallest edge that connects two sets not already connected 1 A C E 3 4 4 2 5 4 MST B D F 1 4 6 A C E G 4 2 5 4 B D F

91 Correctness of Kruskal’s
Never adds an edge that connects already connected vertices Always adds lowest cost edge to connect two sets. By min cut property, that edge must be part of the MST

92 Running time of Kruskal’s

93 Running time of Kruskal’s
|V| calls to MakeSet O(|E| log |E|) 2 |E| calls to FindSet |V| calls to Union

94 Running time of Kruskal’s
Disjoint set data structure O(|E| log |E|) + MakeSet FindSet |E| calls Union |V| calls Total |V| O(|V| |E|) |V| O(|V||E| + |E| log |E|) Linked lists O(|V| |E|) |V| O(|E| log |V|) |V| O(|E| log |V|+ |E| log |E|) Linked lists + heuristics O(|E| log |E| )

95 Prim’s algorithm

96 Prim’s algorithm

97 Prim’s algorithm

98 Prim’s algorithm Start at some root node and build out the MST by adding the lowest weighted edge at the frontier

99 Prim’s 1 A C E 3 4 5 MST 4 2 4 B D F A C E 4 6 B D F

100 Prim’s 1 A C E 3 4 5 MST 4 2 4 B D F A C E 4 6 B D F

101 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 4 B D F A C E 4 6 B D F 6

102 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 4 B D F A C E 4 6 B D F 6

103 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 1 4 B D F A C E 4 6 B D F 4 2

104 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 1 4 B D F A C E 4 6 B D F 4 2

105 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 1 4 B D F A C E 4 6 B D F 4 2

106 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 1 4 B D F A C E 4 6 B D F 4 2

107 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 1 4 B D F A C E 4 6 B D F 4 2

108 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 1 4 B D F A C E 4 6 B D F 4 2

109 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 1 4 B D F A C E 4 6 B D F 4 2

110 Prim’s 1 A C E 3 4 5 MST 4 2 4 5 1 4 B D F A C E 4 6 B D F 4 2

111 Correctness of Prim’s? Can we use the min-cut property?
Given a partion S, let edge e be the minimum cost edge that crosses the partition. Every minimum spanning tree contains edge e. Let S be the set of vertices visited so far The only time we add a new edge is if it’s the lowest weight edge from S to V-S

112 Running time of Prim’s

113 Running time of Prim’s Θ(|V|) Θ(|V|) |V| calls to Extract-Min
|E| calls to Decrease-Key

114 Running time of Prim’s Same as Dijksta’s algorithm
1 MakeHeap |V| ExtractMin |E| DecreaseKey Total Array O(|V|) O(|V|2) O(|E|) O(|V|2) Bin heap O(|V|) O(|V| log |V|) O(|E| log |V|) O((|V|+|E|) log |V|) O(|E| log |V|) Fib heap O(|V|) O(|V| log |V|) O(|E|) O(|V| log |V| + |E|) Kruskal’s: O(|E| log |E| )

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