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I am looking for suitable algorithms I could use in a sports team management simulator (e.g. hockey or soccer). Some features of the simulator:

  • The team can play with different formations (e.g. soccer's 4-4-2).
  • Each player in the team has a numeric rating for how good they are for each position in the formation.
  • There is a pool of squad players of varying abilities from which the team can be selected

What algorithms can be used to programmatically and efficiently determine the strongest teams and formations?

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It smells NP-Hard (though I don't have reduction in mind) Would you like heuristical approach? –  amit May 29 '12 at 19:05
Yes please, whatever gets the job done fast! –  Mark McLaren May 29 '12 at 19:06
If it's as "simple" as putting the highest-rated players in each position of the formation, then a greedy algorithm should perform fairly well. I agree with taking the heuristic approach since there's no need to look at every different combination. –  Zairja May 29 '12 at 19:09
@amit NP-complete, I think. May be related to Job-Shop Scheduling Problem, not? –  moooeeeep May 29 '12 at 19:25
Many thanks guys! Wonderful answers, I am really glad I asked this question now. It is very hard for me to pick a winner as I don’t feel qualified! –  Mark McLaren May 29 '12 at 20:29

3 Answers 3

up vote 5 down vote accepted

If we model your problem by graph and noticing that number of different formations is small, the problem is maximum weighted bipartite matching, which is solvable by Hungarian Algorithm, ....

But how to model the problem with bipartite graphs? Set players as one part, and positions as another part (e.g in soccer), to form a pool of players and 11 position for them, connect all players to all positions, and set the corresponding edge weight as a corresponding player rating in the position.

Now all you should do is to find a maximum (weighted) matching in this complete bipartite graph. (codes are available in wiki link).

I supposed we have a limited number of formation, for each formation we can find corresponding matching graph, and then maximum matching, finally take maximum value over all possible formations (in all graphs).

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That fits my requirements perfectly. Thanks. –  Mark McLaren May 29 '12 at 21:47

You could try a heuristical approach using existing AI tools for optimizations, such as Genetic Algorithms or Hill Climbing.
I'll give more details on hill climbing, since it is my favorite.

Represent your problem as states graph G = (V,E) such that V = {all possible states } and E = {(u,v) | swapping one player you can move from u to v }.
Also, let u:V->R be a utility function for a formation.
Since we do not want to generate the graph, let next:V->2^V be a function such that next(v) = {all possible formation that you can get by changing one player }

The idea of hill climbing is to start from a random formation, and greedily make the best change possible, when you are stuck - restart the algorithm from a new random formation.

1. best<- -INFINITY
2. while there is more time
3. choose a random matching
4. NEXT <- next(s)
5. if max{ u(v) | for each v in NEXT} < u(s): //s is a local maximum
   5.1. if u(s) > best: best <- u(s) //if s is better then the previous result - store it.
   5.2. go to 2. //restart the hill climbing from a different random point.
6. else:
   6.1. s <- max { NEXT }
   6.2. goto 4.
7. return best //when out of time, return the best solution found so far.

Note that this variation of hill climbing (hill climbing with random restarts) is an any time algorithm - meaning it will become better when more time is given, and when infinite time is given - it founds the global maximum.

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The simples heuristic that can be applied to your problem is the greedy algorithm, whose explanation can be found at

Another solution is to create two dummy nodes (begin and end) and consider your pool of players as an ordered graph (first comes the goalkeeper, then the right wing defender, and so on). The edges will consist of the players rating for the position under consideration. In this scenarion, you will have a scenario where you can apply the A* algorithm, whose description you will find at*_search_algorithm (just remember that a maximization problem is only a minimization of the inverse function).

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A* is a pathfinding algorithm, I am not sure what path are you looking for, what is the target node in this case? I am not sure I am following this line of thought, would you care to elaborate? :\ –  amit May 29 '12 at 19:16
A* is an heuristic to find the minimum cost path between two nodes. The target would be the dummy node "end" that I told you to create. The multiple paths would be the combinations between all players in each positions. Don't worry about combinatorial explosion, for you would only explore some paths (those that look promising for each iteration of the algorithm). –  rlinden May 29 '12 at 23:39

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