Ain't it true that while counting the moves for 1 tile can lead to other tiles getting to their goal state? And hence counting for each tile can give us a count more than the minimum moves required to reach the goal state?

This question is in context of Manhattan distance for 15-Puzzle.

Here is the Question in different words:

Can we use Manhattan distance as an admissible heuristic for N-Puzzle. To implement A* search we need an admissible heuristic. Is Manhattan heuristic a candidate? If yes, how do you counter the above argument (the first 3 sentences in the question)?

Definitions: A* is a kind of search algorithm. It uses a heuristic function to determine the estimated distance to the goal. As long as this heuristic function never overestimates the distance to the goal, the algorithm will find the shortest path, probably faster than breadth-first search would. A heuristic that satisfies that condition is admissible.

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    Can you give some more background on what the problem is? Depending on the problem, Manhattan distance could either be perfectly admissible or entirely inadmissible. – templatetypedef Dec 31 '10 at 18:05
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    Manhattan Distance is a metric for distance or work, not a class of problems. DESCRIBE the PROBLEM. – San Jacinto Dec 31 '10 at 18:12
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    @San The problem is this en.wikipedia.org/wiki/Fifteen_puzzle – Dr. belisarius Dec 31 '10 at 18:15
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    @belisarius: An "admissible heuristic" in A* search is an estimate of how close you are to your goal that never overstates the distance. That guarantees finding the shortest (or least-cost) path. This is a real question, although one requiring the knowledge of some specific terminology, and should be re-opened. – David Thornley Jan 20 '11 at 15:31
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    @David: it is now reopened, and also retagged so that it has tags that put it where people who have the requisite knowledge can find it. To someone who has the requisite knowledge, the question was mostly clear to begin with, though a link to Wikipedia for the 15 puzzle (or a description of it) would have been a good idea to start with. – Ken Bloom Jan 21 '11 at 16:03

Admissable heuristics must not overestimate the number of moves to solve this problem. Since you can only move the blocks 1 at a time and in only one of 4 directions, the optimal scenario for each block is that it has a clear, unobstructed path to its goal state. This is a M.D. of 1.

The rest of the states for a pair of blocks is sub-optimal, meaning it will take more moves than the M.D. to get the block in the right place. Thus, the heuristic never over-estimate and is admissible.

I will delete when someone posts a correct, formal version of this.

  • I got it! I am sorry for being not so clear. This happened may be because I had not given enough thought to the doubt I was facing – Akhil Dec 31 '10 at 18:28

Formal Proof: By definition of h, h(s∗) = 0, if s∗ is the goal state. Assume for proof by contradiction that C∗ < h(s0) for some initial state s0. Note that, since each action can move only one tile, performing an action can at most reduce h by one. Since the goal can be reached in C∗ actions, we have h(s∗) ≥ h(s0) − C∗ > 0, which brings us to a contradiction since h(s∗) should be zero. Therefore, we must have h(s0) ≤ C∗ forall s0, and h is admissible. (Source: University of California, Irvine)

  • Thank you University of California, Irvine – Abdullah Feb 3 '16 at 22:03
  • Sorry for reviving this old thread. I just wanted to ask how did you arrive at this: h(s∗) ≥ h(s0) − C∗ – LanceHAOH Feb 22 '18 at 15:40

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