# A* algorithm optimality proof when always underestimating

I understand why a* algorithm always gives the most optimal path to a goal state when the heuristic always underestimates but I can't create a formal proof for it.

As far as I understand for each path considered as it goes deeper and deeper the accuracy of f(n) increases until the goal state where it is 100% accurate. Also no incorrect paths are ignored as estimation is < actual cost thus, leading to the optimal path. But how should I create a proof for it?

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The main idea of the proof is that when A* finds a path, it has a found a path that has an estimate lower then the estimate of any other possible paths. Since the estimates are optimistic, the other paths can be safely ignored. Also, A* is only optimal if two conditions are met: 1. The heuristic is admissible, as in, it will never over-estimate the cost. 2. The heuristic is monotonic, meaning, if H(1) < H(2) then RealCost(1) < RealCost(2).

You can prove the optimality to be correct by assuming the opposite, and expanding the implications.

Assume that the path give by A* is not optimal with an admissible and monotonic heuristic, and think about what that means in terms of implications (you'll soon find yourself reaching a contradiction), and thus, your original assumption is reduced to absurd.

From that you can conclude that your original assumption was false, that is, A* is optimal with the above conditions. Q.E.D. ;)

Hope this gets you on the right track.

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I think when it's monotonic you can run the algorithm more efficiently but it's not a necessity. Can you tell me the source you got their information from? –  user972616 Apr 18 '12 at 14:59
It's a necessity if you're applying A* to a Closed Set. From wikipedia (there are other sources): "If the heuristic function is admissible, meaning that it never overestimates the actual minimal cost of reaching the goal, then A* is itself admissible (or optimal) if we do not use a closed set. If a closed set is used, then must also be monotonic (or consistent) for A* to be optimal." –  pcalcao Apr 18 '12 at 15:05
Thanks that makes sense now –  user972616 Apr 18 '12 at 15:33
Sorry pcalcao, but according to your definition, a heuristic is monotonic if $h(n_1) < h(n_2)$ implies $h^*(n_1) < h^*(n_2)$ where $h(n)$ and $h^*(n)$ are the heuristic estimate and true optimal cost. Where do this definition come from? Usually, monotonicity is defined saying that $h(n) \leq c(n,n') + h(n')$ for all $n'$ which is a descendant of any node $n$ in the state space. And I do not see a necessary implication from this definition to yours. All that can be done is to generalize this definition to consistency and then, to admissibility, but not to your property as far as I can say. –  Carlos Linares López Oct 29 '13 at 23:01

Consider that last step, the one that completes the optimal path. Why must A* choose that path? Or, put another way, why must A* avoid choosing a sub-optimal path that reaches the goal? (Hint: this is the reason the heuristic needs to be admissible.) Note that it is OK to choose a sub-optimal path so long as it doesn't complete the path (why?). That should give you some idea of how to fashion a proof.

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