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I am trying to implement the famous game of Tic Tac Toe using Machine learning with Least Mean Square (LMS) rule (an exercise proposed in Tom Mitchell's famous book, Machine Learning).

I made the computer learn by playing against an optimal opponent that picks the best moves, and then against a randomized player. Against the optimal opponent, my program won about 90% of the games and tied the rest without ever losing. Against a random opponent, it won about 83% and lost 15% of the games.

However, when I played against the program, I won every time using the same strategy.

Here's how my program works:
* create learner and player(randomized or optimal)
* while (game running)
* generate all possible states for a turn and use the best to make the turn
* the best turn is saved
* go through saved boards and calculate value for every feature
* calculate board score using features and current weights
* calculate training score:
* if last board and won: trainings value of last board == 100
* if last board and lost: trainings value of last board: -100
* adjust the weights using LMS rule

I expect this approach to make the computer play perfectly (win most of the time, tie otherwise)? Am I wrong, or is there something wrong with my training method?

Thoughts, ideas, code, suggestions on board features to use on this matter are really appreciated.

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    Tic tac toe is solvable with a very short search. What features are you proposing to gather? Given that the number of board positions is small, one could simply create sufficient features to programmatically solve this. Machine learning is not only unnecessary here, but also inappropriate. – Iterator Nov 6 '11 at 1:52
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    I know the state space is small enough for a brute force, but i want to see if Machine Learning can be done here, this was posted as an exercise in Tom Mitchell's book (Machine Learning), and to put my answer in a different way, Is it possible to select certain board features so the learning algorithm can learn to play the game perfectly ? – Ibrahim Najjar Nov 6 '11 at 14:02
  • Yes: the board configuration, up to rotation, can be stored and the game can be played perfectly. I only need a small table of features to describe the board position "classes", make membership in a class a feature, and then score the changes between classes. – Iterator Nov 6 '11 at 15:54
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    "Against the optimal opponent, my program won about 90% of the games" - pretty sure that's not an optimal opponent. – rob mayoff Nov 28 '11 at 6:35
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    As rob mayoff noticed correctly, your optimal opponent for sure isn't optimal (or there's some other bug in your program), as the optimal strategy for tic tac toe never loses. However, when generating training data only from a single opponent using the same strategy all the time, you might overfit to that strategy. Instead, for tic tac toe it makes sense to generate all training data using random plays. – ahans Jan 23 '13 at 21:23
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I did a similar project to this in my senior year at Lehigh, in 1968-1969, when computers ran on water. ;-) One module was an optimal player, and the second module was the learning machine. In the best situation, the learning machine achieved perfect play in a very short number of training games. To make things more interesting, I also inserted a control to have the "optimal" player make random errors, at a rate I could control. I could then measure the rate of learning vs. the "intelligence" of the training partner (no longer optimal). Of significance, the learning machine still managed to become an optimal player, albeit in a bit longer time. Although a trivial game, when one extends the concept along philosophical lines, it does suggest that computers will eventually become much more highly intelligent than their "teachers."

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