I've been presented the following problem in University:

Let *G = (V, E)* be an (undirected) graph with costs *c _{e}* >= 0 on the edges

*e*∈

*E*. Assume you are given a minimum-cost spanning tree

*T*in

*G*. Now assume that a new edge is added to

*G*, connecting two nodes

*v*,

*t*∈

_{v}*V*with cost

*c*.

- Give an efficient algorithm to test if
*T*remains the minimum-cost spanning tree with the new edge added to*G*(but not to the tree*T*). Make your algorithm run in time O(|E|). Can you do it in O(|V|) time? Please note any assumptions you make about what data structure is used to represent the tree*T*and the graph*G*. - Suppose
*T*is no longer the minimum-cost spanning tree. Give a linear-time algorithm (time O(|E|)) to update the tree T to the new minimum-cost spanning tree.

This is the solution I found:

```
Let e1=(a,b) the new edge added
Find in T the shortest path from a to b (BFS)
if e1 is the most expensive edge in the cycle then T remains the MST
else T is not the MST
```

It seems to work but I can easily make this run in O(|V|) time, while the problem asks O(|E|) time. Am I missing something?

By the way we are authorized to ask for help from anyone so I'm not cheating :D