My book here (Artificial intelligence A modern approach) says that the worst-case time and space complexity of a uniform-cost search algorithm would be O(b[C*/e]) , where b is the branching factor, C* is the cost of the optimal solution, and every action costs atleast e. But why is this so?


First, the complexity is O(B^(C/e)) [exponential in C/e].

To understand it, think of a simple example case first:

Let G=(V,E) be a graph, with branch factor B. The graph is unweighted (w(e) = 1 for each e).

Consider finding the shortest path from S to T.
In this case, the algorithm is actually a BFS, and it will discover all nodes in the path up to length SOL, where SOL is the length of the shortest path, which is O(B^|SOL|)

For the general case - the same idea holds, you need to discover all nodes up to cost C. So you discover nodes up to depth C/e, giving you O(B^(C/e)) total nodes needed to be explored.

The exponential factor is because: First level (root) has B^0=1 nodes, second level has B nodes. from each of these you discover B nodes, giving you B^2, ....

Missed it so far, but the title asks for space complexity and not time complexity. However, the answer remains the same, since a uniform cost search holds a visited set, for already visited nodes. Since each node you discover is also added to it - the answer remains O(B^(C/e))

  • But why do you take C/e ? C is the cost of the the goal, and e is the minimum cost of any node. So what's the logic behind this. – Ghost Aug 15 '12 at 13:45
  • @Ghost: C/e is the maximal possible depth you need to traverse. If the goal cost is C, and each edge cost at least e, the total number of edges you can traverse in each path is at most C/e – amit Aug 15 '12 at 13:46
  • So is C* the cost of traversing from the root to the goal node, or the cost of traversing from the node before the goal to the goal node? – Ghost Aug 15 '12 at 13:49
  • @Ghost: From the source to the goal (The sum of costs of all edges on the path leading from source to goal) – amit Aug 15 '12 at 13:51
  • ok , i get it, thanks – Ghost Aug 15 '12 at 13:52

C*/e means average number of nodes which should be visited during the search, and for visiting each of this nodes you should look at all possible b branches (at least root nodes), so you should check b[C*/e] node in your search. which is your search time complexity, this is by assuming process on each node takes O(1).

P.S: It's Ω(b[C*/e])in worst case

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