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.