# How O(V+E) is equal to O(b^d) In BFS [closed]

In my algoritham analysis course teacher taught us that the time complexity of Breath First search is O(V+E) but now in Artificial intelligence course teacher is saying that the complexity of BFS is O(bd). When i asked him question he gave me a logical reason i.e "In theoretical computer science , O(V+E ) is appropriate because the graph is an explicit data structure that is input to the search algorithm. In AI, the graph is often represented implicitly by an initial state, action and transition model and frequently infinite. For this reason the complexity is expressed in term of O(bd)". Now I have two questions

1. How O(V+E) and O(bd) are equal the first one looks like a linear complexity and second one is exponential.
2. When we talk about big O notation it means that upper bound whatsoever the input may be it should remains the same because its an upper bound. whether Big O only deals with some finite data input?
Wikipedia source

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## closed as off topic by Wooble, Mark, Kate Gregory, Tichodroma, Peter DeWeeseOct 10 '12 at 13:42

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Will the close voters please provide a comment explaining why they think it is off topic? It discusses the basics of an algorithm often used to solve shortest path problems in many applications, and I see nothing wrong in questions about understanding it. –  amit Oct 10 '12 at 13:32
This question belongs on cs.stackexchange.com. –  Peter DeWeese Oct 10 '12 at 13:42

In Artificial Intelligence - you usually handle with huge/infinite graphs, thus `O(V+E)` is not informative and not good enough for these graphs, so we try to get a better bound. This bound is `O(B^d)`, where `B` is the branch factor and `d` is the depth of the solution. The rational behind this is if you "branch" to B directions at each depth, you end up exploring `O(B^d)` nodes.

Morever - note that the classic BFS from your algorithms course is exploration algorithm - which needs to explore the entire graph (explore all vertices), while in AI we use it as pathfinding - you explore until we find a path from the source to the target. (no need, and sometimes it is impossible to explore the entire graph)

Also note, that if you look on a tree (no node is discovered twice), with branch factor `B` and all leaves are of depth `d` - there are exactly `B + B^2 + B^3 + ... + B^d < B^(d+1)` nodes in the tree, so if you do need to

How O(V+E) and O(b^d) are equal the first one looks like a linear complexity and second one is exponential.

In the first, the graph is the input, so it is linear in the size of the input - the graph.
The second is also linear in the size of the graph - and exponential in the depth of the solution - a different factor, still - no need to traverse a vertex more then once, so still linear in the graph's size.
So, in here - basically `O(B^d)` is a subset of `O(V+E)`, and is more informative then it, if you can 'suffer' the fact that your complexity is a function of `d`, which is not part of the input.

When we talk about big O notation it means that upper bound whatsoever the input may be it should remains the same because its an upper bound. whether Big O only deals with some finite data input?

If the graph is infinite, big O is not informative, for each f(n), and for each constants c,N - `c*f(n) < infinity`, so it is useless when talking about infinite graphs.

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Thanks for reply but according to wikipedia O(V+E) is equal to O(b^d) my question is how both bounds can be equal? –  james Oct 10 '12 at 13:15
@james: See edit, the idea is - you still do not need to traverse an edge nor vertex more then once. Also: Wikipedia is wrong in the cases of infinite graphs - `O(V+E) != O(B^d)`. If `V = infinity`, then O(V+E) is basically O(infnity), and `2^(B^d)` is also in it, while it is not in `O(B^d)` –  amit Oct 10 '12 at 13:19
@james: Also note (just a side note), `d` is NOT a factor of the input. Theoretical algorithms researchers prefer using the big O notation and analysis only on factor of the input, focusing on the theoretical aspects rather then practical ones. AI researchers are less bounded to these constraints. The `O(B^d)` is probably the only big O notation you will see in AI course, in my research and in my proffessor's researches - we usually use other methods and use statistical tools on empirical data to check which algorithm is better. –  amit Oct 10 '12 at 13:29