# Travelling salesman with repeat nodes & dynamic weights

Given a list of cities and the cost to fly between each city, I am trying to find the cheapest itinerary that visits all of these cities. I am currently using a MATLAB solution to find the cheapest route, but I'd now like to modify the algorithm to allow the following:

1. repeat nodes - repeat nodes should be allowed, since travelling via hub cities can often result in a cheaper route
2. dynamic edge weights - return/round-trip flights have a different (usually lower) cost to two equivalent one-way flights

For now, I am ignoring the issue of flight dates and assuming that it is possible to travel from any city to any other city.

Does anyone have any ideas how to solve this problem? My first idea was to use an evolutionary optimisation method like GA or ACO to solve point 2, and simply adjust the edge weights when evaluating the objective function based on whether the itinerary contains return/round-trip flights, but perhaps somebody else has a better idea.

(Note: I am using MATLAB, but I am not specifically looking for coded solutions, more just high-level ideas about what algorithms can be used.)

Edit - after thinking about this some more, allowing "repeat nodes" seems to be too loose of a constraint. We could further constrain the problem so that, although nodes can be repeatedly visited, each directed edge can only be visited at most once. It seems reasonable to ignore any itineraries which include the same flight in the same direction more than once.

• Your description of "dynamic edge weights" just sounds like directed edges with different weights in each direction. – Matt Ball Mar 12 '11 at 4:39
• @Matt - Not sure I understand. Let's say one-way flights are \$50 in each direction, or a return flight is \$60. What would the weights be in each direction? – del Mar 12 '11 at 4:47
• By "return flight," do you mean a round-trip ticket? (I think that's a British-ism). If so, you could create this by having the two vertices connected by multiple paths (\$50 each way ones, and \$30 each way) if you have some way to enforce that, for the second path (round-trip tickets), if the outgoing \$30 path is taken then the incoming \$30 one must also be taken. – Matt Ball Mar 12 '11 at 4:51
• Yes, I meant round-trip. I didn't realise "return trip" is a British term, I have edited the question to clarify. – del Mar 12 '11 at 4:55
• And the "separated by a common language" cliche finds another victim... :) – dappawit Mar 12 '11 at 6:39

I haven't tested it myself; however, I have read that implementing Simulated Annealing to solve the TSP (or variants of it) can produce excellent results. The key point here is that Simulated Annealing is very easy to implement and requires minimal tweaking, while approximation algorithms can take much longer to implement and are probably more error prone. Skiena also has a page dedicated to specific TSP solvers.

• I've tested it with an ACO-algorithm and is a bit like gambling. Mostly it can produce good result but it's not guaranteed while christofides is always withn the 3/2 optimum. But you are right christofides is very expensive to implement and there is no open-source solution. – Gigamegs Mar 14 '11 at 18:06

If you want the cost of the solution produced by the algorithm is within 3/2 of the optimum then you want the Christofides algorithm. ACO and GA don't have a guaranteed cost.

• @epitaph- Can you apply Christofides here? We're not guaranteed that the triangle inequality holds. – templatetypedef Mar 13 '11 at 5:31
• @templatetypedef: I don't have any formal cs or math degree so I'm just guessing: OP is not looking for code and why is en.wikipedia.org/wiki/Triangle_inequality not working with return flights? I can construct a MST with a round-trip and still looking for triangle inequality? The other problem is to find a triangle inequality because this is very expensive! – Gigamegs Mar 14 '11 at 17:58
• The triangle equality must hold to use Christofides because TSP without the triangle inequality is NP-hard to approximate within any constant factor. Without that guarantee, Christofides is not guaranteed to give a good result. – templatetypedef Mar 14 '11 at 18:22
• @templatetypedef: Do you repeat Christofides or Wikipedia here? I did christofides? – Gigamegs Mar 14 '11 at 18:26
• I'm not sure I understand what you're saying. My argument is that because we don't know that the triangle inequality holds in the original setup, even ignoring the round-trip costs, Christofides cannot be applied here because it makes strong assumptions about the edge costs. – templatetypedef Mar 14 '11 at 18:33

Solving the TSP is a NP-hard problem for its subcycles elimination constraints, if you remove any of them (for your hub cities) you just make the problem easier.

But watch out: TSP has similarities with association problem in the meaning that you could obtain non-valid itineraries like:

Cities: New York, Boston, Dallas, Toronto

Path:

Boston - New York New York - Boston

Dallas - Toronto Toronto - Dallas

which is clearly wrong since we don't go across all cities.

The subcycle elimination constraints serve just to this purpose. Including a 'hub city' sounds like you need to add weights to the point and make an hybrid between flux problems and tsp problems. Sounds pretty hard but the first try may be: eliminate the subcycles constraints relative to your hub cities (and leave all the others). You can then link the subcycles obtained for the hub cities together.

Good luck

Firstly, what is approximate number of cities in your problem set? (Up to 100? More than 100?) I have a fair bit of experience with GA (not ACO), and like epitaph says, it has a bit of gambling aspect. For some input, it might stop at a brutally inefficient solution. So, what I have done in the past is to use GA as the first option, compare the answer to some lower bound, and if that seems to be "way off", then run a second (usually a less efficient) algorithm.

Of course, I used plenty of terms that were not standard, so let us make sure that we agree what they would be in this context:

1. lower bound - of course, in this case, MST would be a lower bound.
2. "Way Off" - If triangle inequality holds, then an upper bound is UB = 2 * MST. A good "way off" in this context would be 2 * UB.
3. Second algorithm - In this case, both a linear programming based approach and Christofides would be good choices.
• It would be less than 100 cities. Currently I'm experimenting with around 15. Could you give any further clarification as to why linear programming or Christofides are good choices for this problem? Do they allow repeat nodes and dynamic weights? – del Mar 27 '11 at 14:31
• I'm not others, my name is epitaph. Thank you for answer! – Gigamegs Mar 29 '11 at 13:21
• @epitaph: Fixed that! (Obviously, I should read the names better) – Josh Mar 30 '11 at 22:40
• Thanks, mate. Sorry for the downvote. Too bad OP isn't give the bounty! What do you think of user templatetypedef? Isn't it a bizarr discussion? – Gigamegs Mar 31 '11 at 10:01

If you limit the problem to round-trips (i.e. the salesman can only buy round-trip tickets), then it can be represented by an undirected graph, and the problem boils down to finding the minimum spanning tree, which can be done efficiently.

In the general case I don't know of a clever way to use efficient algorithms; GA or similar might be a good way to go.

• Good idea, but I am looking for a more general solution that doesn't constrain the itinerary to round-trips. – del May 5 '11 at 9:42
• Ok. In any case I advise you not to think of your problem as a TSP, because it is so far removed from the original TSP that I really doubt you can carry any useful techniques over. – mitchus May 5 '11 at 13:23

Do you want a near-optimal solution, or do you want the optimal solution?

For the optimal solution, there's still good ol' brute force. Due to requirement 1 involving repeat nodes, you'll have to make sure you search breadth-first, not dept-first. Otherwise you can end up in an infinite loop. You can slowly drop all routes that exceed your current minimum until all routes are exhausted and the minimal route is discovered.

• I'm looking for a near-optimal solution. Take a look at the extra constraint I added to the end of my question - each flight can only be taken once (i.e. each directed edge of the graph can only be traversed once), so neither BFS nor DFS will result in an infinite loop. – del Jul 21 '11 at 4:26