I have an undirected graph similar to the one below, I need to implement a graph traversing algorithm.
**Example**:

http://i.imgur.com/15L6m.png

The idea is that each vertex is a city, and each edge is a road.

The weight of an edge represents the time needed to traverse the specified edge.

The conditions are:

- Each edge is open for traversal in a specified time window: Time Open1, Time Open2, TimeClose1, Time Close2 - the current time must be in these intervals in order to traverse the edge.
- Only some vertices must be visited. The vertices must be visited at leas once in the specified time window for each one: Time Open1, Time Open2, TimeClose1, Time Close2 - the current time must be in these intervals in order to mark the vertex as visited.
- The starting point is always vertex 0

For **my example** I have:

Vertices that must be visited and their time window (values with -1 are not taken into consideration):

```
Vertex To1 Tc1 To2 Tc2
1 0 260 340 770
4 0 240 -1 -1
5 170 450 -1 -1
```

Edges are open in the following time window (values with -1 are not taken into consideration):

```
Edge To1 Tc1 To2 Tc2
0-1 0 770 -1 -1
0-4 0 210 230 770
0-5 0 260 -1 -1
1-2 0 160 230 770
1-5 40 770 -1 -1
2-4 80 500 -1 -1
3-4 60 770 -1 -1
3-5 0 770 -1 -1
```

So the basic idea is to start with vertex 0 and find the shortest route to traverse
vertices 1, 4 and 5 taking in consideration the specified time.

Also if for example you have done 0-1 but you can't use 1-5 you can do 0-1-0-1-5.

A possible solution I'm working with now is:

Start with 0. Find the nearest vertex to mark in the shortest time period (I use a
modified Dijkstra algorithm). Do this until I have marked all the vertices needed.

The **problem** is that I don't think I'm finding all the possibilities, because as I said
you can also move around like the 0-1-0-1-5 combination and in the end you might end up with a shorter route.

In order to make it more clear, I have to find the shortest path so that I start with vertex 0, end with one target vertex while I have visited all other target vertices at least once respecting the conditions imposed on the edges and target vertices.

For example:

A possible solution is 0 - 4 - 3 - 5 - 1 with a total time of 60+50+60+50=220

From 0 I can also go directly to 5 but as stated in conditions in order to mark vertex 5
I must have a cumulative time between 170 and 450. Also if I go 0-4 I can't use edge 4-2 because it opens at 80 and my cumulative time is 60. Note I can use 0-4-3 because 4-3 opens at 60 and to do 0-4 it takes a time equal to 60.

First of all the constraints are that I will use a maximum of 20 vertices and about 50 edges at max.

Solution 1:

0

1 4 5
0 2 5 0 2 3 0 1 3

What I do is traverse the graph by visiting each neighboring vertex building something similar to a tree. I stop expanding a branch when :

1. I have too many duplicates like I have 0 1 0 4 0 1 0 - so I stop because I have a set number of duplicate 0 values which is 4

2. I find a road that contains all the vertices to mark

3. I find a road that takes longer than another complete road

4. I can't create another node because the edge is closed

Solution 2:

Applying @Boris Strandjev example, but I have some problems:

I have to visit nodes 1,4 and 5 at least once in their interval, visits outside the intervals are allowed but not marked. For a vertex I have {(< id1, id2id3id4>, time)}, where id1 is the ide of the current vertex, and id2-4 represent bool vals for 1,4,5 if were visited in the specified intervals, time - current time in path

```
Step1:
{<0, 000>, 0} I can visit - {<1, 100>, 60} - chosen first lowest val
- {<4, 010>, 60}
- {<5, 000>, 60}
Step2:
{<1, 100>, 60} - {<0, 100>, 120}
- {<2, 100>, 110} - chosen
- {<5, 100>, 110}
Step3:
{<2, 100>, 110} - {<1, 100>, 160} - if I choose 1 again I will have a just go into a loop
- {<4, 110>, 170}
Step4:
{<4, 110>, 170} - {<0, 110>, 230}
- {<2, 110>, 230}
- {<3, 110>, 220} - chosen
Step5:
{<3, 110>, 220} - {<4, 110>, 270} - again possible loop
- {<5, 111>, 280}
Step6:
{<5, 111>, 280} - I stop Path: 0-1-2-4-3-5 cost 280
```

**Edit:**

I ended up using a combination of the 2 solutions above. Everything seems to work fine.

`{<4, 010>, 60}`

or`{<5, 000>, 60}`

, because it is with lower time than`{<2, 100>, 110}`

. Overall after step 2 you have 5 augmenting paths to choose from:`{<4, 010>, 60}, {<5, 000>, 60}, {<0, 100>, 120} , {<2, 100>, 110}, {<5, 100>, 110}`

. I am sorry maybe my example is a bit confusing after all... – Boris Strandjev Sep 23 '12 at 17:51