Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I am trying to find the optimal solution to a Sliding Block Puzzle of any length using the A* algorithm.

The Sliding Block Puzzle is a game with white (W) and black tiles (B) arranged on a linear game board with a single empty space(-). Given the initial state of the board, the aim of the game is to arrange the tiles into a target pattern.

For example my current state on the board is BBW-WWB and I have to achieve BBB-WWW state. Tiles can move in these ways : 1. slide into an adjacent empty space with a cost of 1. 2. hop over another tile into the empty space with a cost of 1. 3. hop over 2 tiles into the empty space with a cost of 2.

I have everything implemented, but I am not sure about the heuristic function. It computes the shortest distance (minimal cost) possible for a misplaced tile in current state to a closest placed same color tile in goal state.

Considering the given problem for the current state BWB-W and goal state BB-WW the heuristic function gives me a result of 3. (according to minimal distance: B=0 + W=2 + B=1 + W=0). But the actual cost of reaching the goal is not 3 (moving the misplaced W => cost 1 then the misplaced B => cost 1) but 2.

My question is: should I compute the minimal distance this way and don't care about the overestimation, or should I divide it by 2? According to the ways tiles can move, one tile can for the same cost overcome twice as much(see moves 1 and 2).

I tried both versions. While the divided distance gives better final path cost to the achieved goal, it visits more nodes => takes more time than the not divided one. What is the proper way to compute it? Which one should I use?

share|improve this question

Your heuristic is not admissible, so your A* is not guaranteed to find the optimal answer every time. An admissible heuristic must never overestimate the cost.

A better heuristic than dividing your heuristic cost by 3, would be: instead of adding the distance D of each letter to its final position, add ceil(D/2). This way, a letter 1 or 2 away, gets a 1 value, 3 or 4 away, gets a 2 value, an so on.

share|improve this answer

It is not obvious to me what an admissible heuristic function for this problem looks like, so I won't commit to saying, "Use the divided by two function." But I will tell you that the naive function you came up with is not admissible, and therefore will not give you good performance. In order for A* to work properly, the heuristic used must be admissible; in order to be admissible, the heuristic must absolutely always give an optimistic estimate. This one doesn't, for exactly the reason you highlight in your example.

(Although now that I think about it, dividing by two does seem like a reasonable way to force admissibility. I'm just not going to commit to it.)

share|improve this answer
    
I'm willing to commit to dividing by 2. The best that you can ever do is move 2 spaces for 1 cost. So dividing by 2 gives you a best case scenario, which will be admissible and consistent. – seaotternerd Oct 1 '14 at 20:13

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.