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Hi! I'm trying to implement an alpha-beta search, but i first want to understand all the logic behind it, not just implementing it using some kind of pseudo code.

What i understand is this: A white player makes a move(let's call it move1). The first move is saved as alpha (the minimum value the player is assured of). Now, if we move to the next possible move by white(move2), and see that the black player's first response results a valuation that is worse than alpha, we can skip all possible black's counter moves as we already know that when white makes move2, the worst possible result is worse than move1's worst possible result.

But, what i don't understand is that beta variable. From chess programming wiki i read : ' the maximum score the minimizing player is assured of '. But i can't really get the idea behind it.

Can somebody please explain it in very simple terms? Thank you very much.

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2 Answers 2

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In chess, there is no easy way to tell if move1 is better than move2 (from your example). An approximation is achieved by looking at "hard" parameters: Number and value of pieces, presence of double or free pawns, ... Usually such an approximation is plugged into the minimax algorithm.


Simply speaking, the idea is as follows: First, all possible moves are expanded (white-black-white-black-...) until a predefined depth or time limit has been reached. This creates a tree of board positions (with moves as edges), and the leaves are evaluated using an heuristics (as described above). Then, the tree is collapsed, leading in the end to an evaluation of move1 vs. move 2.

How does the collapsing work? It starts at the leaves of the tree and assigns a value to each node (aka board position). For each node for which the value of all children is known, the childs' values are aggregated: If it's white's turn, then the best value for white is taken (max); if it's black's turn, the worst (min). Hence the name minimax. This is repeated until the root has been reached.

Assume the following tree of board positions:

|  \
B1  B2
|   |  \
A11 A21 A22

Now assume the following evaluation: A11 = 0, A21 = -1, A22 = +1 (positive value is good for white). We assume from our approximation that position A21 is better than A22 (for black), so we assign -1 to the node B2. For B1 this is clear, its value is 0. Now we assume that B1 is better than B2 for white, hence A's value is 0, and white should move to achive position B1.

Alpha-beta pruning

The idea here is not to build the whole tree, but to do a depth-first search for the more promising moves in order to achieve an early cutoff. In the example above, if we walk the tree depth-first from left to right (A-B1-A11-B2-A21-...), we know after evaluating A21 that position B2 is worse than position B1 for white. Hence, there is no need to evaluate A22 anymore. Alpha and beta simply store the evaluations of the currently known best possible move for white, and the currently known best possible reply for black. The order in which the nodes of the tree are walked (initial ordering) determines if and how many cutoffs are possible. From Wikipedia:

Normally during alpha-beta, the subtrees are temporarily dominated by either a first player advantage (when many first player moves are good, and at each search depth the first move checked by the first player is adequate, but all second player responses are required to try to find a refutation), or vice versa. ...

If ordering is suboptimal, more subtrees will have to be explored completely.

See also iterative deepening depth-first search.


Strictly speaking, the tree is a DAG, as identical board positions can be achieved through different combinations of moves (e.g., transpositons). Employ a hash table to detect identical positions, this is going to save a lot of computational effort.

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Thank you, but i think you kind of missed the question. Or maybe i'm just lacking clarity. But I specifically wanted to know about the variable beta, as i don't understand the sentence 'the maximum value the minimizing player is assured of'. I already know the general idea behind alpha-beta and chess evaluation funcitons. –  geekkid Sep 17 '12 at 20:26
you just alternate as you go up the tree maximizing(alpha(player1)) and minimizing(beta(player2)) ... at least as far as I remember (you may need to minimize alpha and maximize beta depending on your heuristic) –  Joran Beasley Sep 17 '12 at 20:31
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Basically the idea is that alpha and beta are an upper and lower bound on the optimal result, from what you've already explored of the game tree, so that anything outside those bounds isn't worth exploring.

It's been a while since I understood minimax and alpha-beta pruning in detail, but here's the gist as I remember.

As you said, if we already know that white's move1 has score 10, and while examining move2 we find that black can respond in such a way that white is forced into a best score of 8, then it's not worth examining move2 any further; we already know that the best we can possibly do is worse than another option we know about.

But that's only one half of the minimax algorithm. Say we're now examining white's move3, and looking at all of black's responses. We explore black's moveX, and find that one of white's responses to that can force a score of at least 15. If we then start exploring black's moveY (still a response to white's original move3) and find a response by white to moveY that would force a score of at least 18, then we immediately know that the whole game-tree stemming from black's moveY is pointless; black would never make moveY, since moveX only forces black to allow white to score 15, while moveY forces black to allow white to score 18.

Alpha represents a minimum score we already know white can force by making different choices leading up to the point we're exploring. So it's not worth continuing to explore any path once we know there's no possibility of getting more than alpha, since white wouldn't allow us to reach that path.

Beta represents a maximum score we already know that black can force by making different choices leading up to the point we're exploring. So it's not worth continuing to explore any path once we know there's no possibility of getting less than beta, since black wouldn't allow us to reach that path.

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