The complexity of Dijkstra's shortest path algorithm is:

```
O(|E| |decrease-key(Q)| + |V| |extract-min(Q)|)
```

where `Q`

is the min-priority queue ordering vertices by their current distance estimate.

For both a Fibonacci heap and a binary heap, the complexity of the extract-min operation on this queue is `O(log |V|)`

. This explains the common `|V| log |V|`

part in the sum. For a queue implemented with an unsorted array, the extract-min operation would have a complexity of `O(|V|)`

(the whole queue has to be traversed) and this part of the sum would be `O(|V|^2)`

.

In the remaining part of the sum (the one with the edge factor |E|), the `O(1)`

v.s. `O(log |V|)`

difference comes precisely from using respectively a Fibonacci heap as opposed to a binary heap. The decrease key operation which may happen for every edge has exactly this complexity. So the remaining part of the sum eventually has complexity `O(|E|)`

for a Fibonacci heap and `O(|E| log |V|)`

for a binary heap.
For a queue implemented with an unsorted array, the decrease-key operation would have a constant-time complexity (the queue directly stores the keys indexed by the vertices) and this part of the sum would thus be `O(|E|)`

, which is also `O(|V|^2)`

.

To summarize:

- Fibonacci heap:
`O(|E| + |V| log |V|)`

- binary heap:
`O((|E| + |V|) log |V|)`

- unsorted array:
`O(|V|^2)`

Since, in the general case `|E| = O(|V|^2)`

, these can't be simplified further without making further assumptions on the kind of graphs dealt with.