1 outline minimum spanning tree maximal flow algorithm lp formulation
TRANSCRIPT
1
OutlineOutline
Minimum Spanning Tree
Maximal Flow Algorithm LP formulation
2
The Minimum Spanning Tree Problem
最小延展樹問題
3
8.1.2 The Minimum Spanning Tree Problem
application context nodes are cities (節點是城市) arcs are potential highways to be built to connect the cities (線段是連接城市的高速公路)
what is the cheapest way (i.e., shortest total distance) to have all cities connected? (最短的公路網將所有城市連接起來)
4
8.1.2 The Minimum Spanning Tree Problem
general concept tree: a connected network such that the n nodes
of the network are connected by n-1 arcs which is a tree?
5
8.1.2 The Minimum Spanning Tree Problem
think about this the cheapest way to connect all cities should be
a tree called spanning tree, as it connects all cities
the only question: how to find the cheapest spanning tree?
只要細想,每個人都懂。
6
8.1.2 The Minimum Spanning Tree Problem
question: would the cheapest arc always in the minimum spanning tree?
must be
an arc in the spanning tree
an arc not in the spanning tree
the cheapest arc, not in the spanning tree
7
8.1.2 The Minimum Spanning Tree Problem
question: would we find the minimum spanning tree by always selecting the cheapest unselected arc?
no, see, e.g., the cheapest three arcs.
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
8
8.1.2 The Minimum Spanning Tree Problem
Let us grow the minimum spanning tree step by step, i.e., add the arcs one by one. (一步一步的養大這minimum spanning tree. )
As argued before, arc (1, 2) must be in the minimum spanning tree.
Thus, we have a small tree T{1, 2}.
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
331
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
9
8.1.2 The Minimum Spanning Tree Problem
In the minimum spanning tree, which of the three arcs, (1, 3), (2, 3), and (2, 4), should be connected to the tree T{1, 2} grown so far?
Arc (1, 3) of length 18 should be in the minimum spanning tree. Why?
Considered a spanning tree without arc (1, 3).
The cost of the spanning tree can be reduced by swapping an arc with higher cost with arc (1, 3).
Thus, arc (1, 3) should be in the minimum spanning tree.
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
331
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
10
8.1.2 The Minimum Spanning Tree Problem
to find the minimum spanning tree: start with the arc of minimum cost to from a
tree (從最便宜的公路開始) grow the tree by adding an arc connecting to it
such that (每次加一條公路) adding the arc maintains a tree (保持 tree的形式) , and
among possible arcs to add, the added arc is of the lowest cost (選能加上的公路中最便宜的)
11
8.1.2 The Minimum Spanning Tree Problem
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
12
8.1.2 The Minimum Spanning Tree Problem
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
13
8.1.2 The Minimum Spanning Tree Problem
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
14
8.1.2 The Minimum Spanning Tree Problem
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
15
8.1.2 The Minimum Spanning Tree Problem
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
16
8.1.2 The Minimum Spanning Tree Problem
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
17
8.1.2 The Minimum Spanning Tree Problem
1
4
3
5
6
7
213
18
20
22
27
30
49
18
26
24
32
33
18
The Maximal Flow Problem最大流量問題
19
Railway Map Each railway
segment has a capacity (i.e., upper bound of tonnage (per day)).
What is the maximal flow from, say, Paris to Moscow?
http://www.worldchanging.com/archives/009028.html
20
The Maximal Flow Problem
The number beside an arc is the capacity of flow along the arc. (管線旁的數字是管線的容量) The movement can be of either direction.
What is the maximal flow from node 1 to node 4?
1 4
3
210
3
2
6
6
21
The Maximal Flow Problem
At any moment, we need to keep track of the flow and the residual capacity (i.e., remaining capacity) of an arc.
1 4
3
20
0
0
0
0
10 6
2
63
0 0
number beside an arc: boxed = residual capacity, normal = current flow.
22
The Maximal Flow Problem
1 4
3
26
0
0
6
0
4 0
2
63
6 6
1 4
3
20
0
0
0
0
10 6
2
63
0 0
The route 124 allows a flow of 6 units.
23
The Maximal Flow Problem
1 4
3
26
0
0
6
0
4 0
2
63
6 6
1 4
3
28
0
2
6
2
2 0
0
43
6 66+2 6+2
The route 1234 allows a flow of 2 units.
24
The Maximal Flow Problem
The route 134 allows a a flow of 3 units.
1 4
3
28
0
2
6
2
2 0
0
43
6 66+2 6+2
1 4
3
28
3
2
6
2+3
2 0
0
10
6 66+2 6+2
6+2+3 6+2+3
25
The Maximal Flow Problem
The maximal flow from node 1 to node 4 is 11 units. The flow pattern is shown below, with the residual capacities of arcs boxed.
1 4
3
28
3
2
6
5
11 11
0
0
0
1
2
26
The Maximal Flow Problem
The method seems all right: We first find a route of positive flow from the
source to the sink. Find the residual capacities of arcs by
subtracting added flows from their (residual) capacities.
Keep on repeating the above two steps until no route with positive flow can be added.
However, the method can run into trouble.
27
The Maximal Flow Problem
1 4
3
210
3
2
6
6
1 4
3
20
0
0
0
0
10 6
2
63
0 0
28
The Maximal Flow Problem
1 4
3
20
0
0
0
0
10 6
2
63
0 0
1 4
3
20
2
2
2
0
10 4
0
61
2 2
The route 1324 allows a flow of 2 units.
29
The Maximal Flow Problem
1 4
3
24
2
2
6
0
6 0
0
61
6 6
The route 124 allows a flow of 4 units.
1 4
3
20
2
2
2
0
10 4
0
61
2 2
30
The Maximal Flow Problem
1 4
3
24
3
2
6
1
6 0
0
50
7 7
The route 134 allows a flow of 1 unit.
1 4
3
24
2
2
6
0
6 0
0
61
6 6
31
The Maximal Flow Problem
There seems to be no more flow to node 4, because residual capacity of arc (1, 3) = 0, arc (2, 3) = 0, arc (2, 4) = 0
1 4
3
24
3
2
6
1
6 0
0
50
7 7
32
The Maximal Flow Problem
However, this does not make sense, because the flow is found to be 11 units before.
What is wrong?
1 4
3
24
3
2
6
1
7 7
33
The Maximal Flow Problem
Compare the two flow patterns. Any observations?
In the second case, the flow in the vertical arc is in the wrong direction.
1 4
3
28
32
6
511 11
00
0
1
2
1 4
3
24
32
6
1
6 00
50
7 7
34
The Maximal Flow Problem
In a large network, how can we be sure which direction to follow when we add flows one by one?
There should be ways to revert the direction of a wrong flow.
1 4
3
24
2
2
4
1
7 72
1
35
The Maximal Flow Problem
Suppose that we send 2 units from node 1 to node 2 to take up the capacity of node 2 to node 4 of the red flow.
The red flow is along arc (3, 2) is then re-directed to arc (3, 4).
1 4
3
24
2
2
4
1
7 72
1 5
00
0
61 4
3
24
2
4
1
7+2 7+22
1
2
2
36
The Maximal Flow Problem
The result:
Two more units of flow can be sent along the route 1234
1 4
3
26
3
0
6
3
9 9
3
02
0
4
1 4
3
26+2
3
2
6
5
9+2 9+2
1
00
0
2
37
The Maximal Flow Problem There is a labeling algorithm basically keeping track
of the flows, the residual capacities, and the re-direction of flows.
The algorithm works for networks with capacity limits on bi-directional flows on arcs. It is possible to have different limits for the two directions of the same arc. (容許 i 到 j 跟 j 到 i 的 capacity不一樣)
i j3 5
the capacity of i j flow the capacity of j i flow
38
The Maximal Flow Problem
Find the maximal flow from node 1 to node 4 for the following network. The number beside an arc is the capacity limit of the arc. All arcs are bi-directional.
1 4
3
210
3
2
6
6
39
The Maximal Flow Problem Since node 1 is the source, flow can only be possible from
node 1 to node 2. Thus, arc (1, 2) is practically a directed arc.
Similar, flow can only be possible from node 1 to node 3, node 2 to node 4, and node 3 to node 4. Thus, practically arcs (1, 3), (2, 4), and (3, 4) are directed arcs.
The flow on (2, 3) can be on either direction.
1 4
3
2
10
3
2
6
6
0
0
0
0
2
40
The Maximal Flow Problem
1 4
3
2
10
3
2
6
6
0
0
0
0
2
00
The route 1324 allows a flow of 2 units.
2
the residual capacity of flowing from node 1 to node 3
the residual capacity of flowing from node 3 to node 1
1 4
3
2
10
3
2
6
6
0
0
0
0
2
002
2
10
4 2
4
2
41
The Maximal Flow Problem
The route 124 allows a flow of 4 units.
1 4
3
2
10
3
2
6
6
0
0
0
0
2
002
2
10
4 2
4
2
1 4
3
2
10
3
2
6
6
0
0
0
0
2
002
2
10
4 2
4
2 66 64
0
6
42
The Maximal Flow Problem
The route 134 allows a flow of 1 unit.2
1 4
3
2
10
3
2
6
6
0
0
0
0
2
002
10
4 2
4
2 66 64
0
6
2
1 4
3
2
10
3
2
6
6
0
0
0
0
2
002
2
10
4 2
4
2 66 64
0
6 77
03
5
1
43
The Maximal Flow Problem
The route 1234 allows a flow of 4 unit.
1 4
3
2
10
3
2
6
6
0
0
0
0
2
002
2
10
4 2
4
2 66 64
0
6 77
03
5
1
1 4
3
2
10
3
2
6
6
0
0
0
0
2
002
2
10
4 2
4
2 66 64
0
6 77
03
5
15
11
4
0
8
1
211
44
The Maximal Flow Problem
How to get the flows?
Compare with the original. The differences in (residual) capacities give the actual flows.
1 4
3
2
2
0
0
0
1
8
3
5
6
4
1111
1 4
3
2
10
3
2
6
6
0
0
0
0
2
00
12: 8 units 13: 3 units
23: 2 units 24: 6 units
34: 5 units
maximal flow from node 1 to node 4 : 11 units
45
A Linear Program Formulation of
the Maximal Flow Problem
46
LP Formulation of the Maximal Flow Problem
Oil is pumped out at node 1, temporarily stored at nodes 2, 3, and 4, and eventually sent the refinery at node 5 through the pipe lines. In the following, arc represents a pipe line, with its capacity (i.e., barrels of oil per day) written beside it. Formulate a linear program to find the maximal amount of oil sent from node 1 to node 5. A maximal flow problem can be formulated as a linear program
(and solved by an optimizer).
1 4
3
245
35
4025
10
5
50
20
15
47
LP Formulation of the Maximal Flow Problem
Let xij be the number of barrels of oil pumped from node i to node j; xij 0.
Because node 1 is the source, x21 = x31 = 0.
Similarly, x52 = x53 = x54 = 0 because node 5 is the sink.
Because we do not know the direction of flow in arc (2, 3), we are not sure which of x23 and x32 should be equal to zero.
Similarly, we have no idea of fixing which of x24 and x42, and of x34 and x43, to zero.
1 4
3
245
35
40 25
10
5
50
2015
48
LP Formulation of the Maximal Flow Problem
We further introduce a variable x51. Effectively we act an artificial arc from node 5 to node 1.
1 4
3
245
35
4025
10
5
50
20
15
x51
49
LP Formulation of the Maximal Flow Problem
Each LP constraint matches with a physical relationship of the problem.
There are two types of constraints: conservation of flow: the amount of oil into a
node must be the same as the amount out of the node.
bounds on flow: 0 xij capacity of i to j flow
50
LP Formulation of the Maximal Flow Problem
objective function: max x51, conservation of flow
node 1: x51 = x12 + x13, node 2: x12 + x32 + x42 = x23 + x24 + x25, node 3: x13 + x23 + x43 = x32 + x34 + x35, node 4: x24 + x34 = x42 + x43 + x45, node 5: x25 + x35 + x45 = x51,
1 4
3
245
35
40 25
10
5
50
2015
51
LP Formulation of the Maximal Flow Problem
bounds: 0 x12 45, 0 x13 35, 0 x23, x32 40, 0 x24, x42 25, 0 x25 50, 0 x34, x43 10, 0 x35 15, 0 x45 20
1 4
3
245
35
4025
10
5
50
20
15
52
LP Formulation of the Maximal Flow Problem
Read Example 8-6 for more example.
53
Assignment #3
Chapter 8 Problem 1 (a), (b), plus
(c) Formulate this problem as a mathematical programming model.
Problem 10 Problem 16 (a) Find the maximal flow of this
network, and (b) Formulate the problem as a linear program.