# Monte Carlo Tree Search: Tree Policy for two player games

I am a little confused about how the MCTS "Tree Policy" is implemented. Every paper or article I read talks about going down the tree from the current game state(in MCTS teminology: the root for the player about to make a move). My question is how am I selecting the best child even when I am at the MIN player level ( assuming I am the MAX player). Even if I select some particular action that MIN might take, and my search tree gets deeper through that node, the MIN player during its turn might just as well choose some different node.( If the min player is a amateur human it might just as well choose some node which is not necessarily the best). This kind of makes MAX's entire work in propagating through that node futile since the MIN has chosen a different node. For the steps I am referring to : https://jeffbradberry.com/posts/2015/09/intro-to-monte-carlo-tree-search/ where the tree policy : https://jeffbradberry.com/images/mcts_selection.png kind of makes me believe that they are executing it from a single player perspective.

• I;m not seeing any Python in the question. Commented Feb 17, 2017 at 15:57
• Exploitative play requires opponent modelling. For most games it's turned out that assuming the opponent plays optimally is good enough. Poker might be an exception. Commented Feb 17, 2017 at 16:26
• Sorry Peter for the tag! I am new to SE and I code mostly in python. Now I realize it was irrelevant. Commented Feb 17, 2017 at 19:08
• Paul, then when I implement the "Tree Policy", should I select the best child from MIN's P.O.V. when i am at the level where MIN player would make a move? Commented Feb 17, 2017 at 19:08
• @AvisekNaug Yes you try to pick the best move for the MIN player. Commented Feb 17, 2017 at 20:01

For MCTS, you need some way of generating a reasonable estimate of the probability distribution of possible moves. For AlphaGo [1], this is the fast rollout probability, $p_\pi$ in the paper, which takes a state and outputs a rough probability distribution over all possible moves. The AlphaGo team implemented this as a shallow neural net trained first on expert games, and then improved by playing against itself.