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
To understand it, think of a simple example case first:
G=(V,E) be a graph, with branch factor
B. The graph is unweighted (
w(e) = 1 for each
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 is the length of the shortest path, which is
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
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
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