Both BFS and Dijkstra could be used to find the *shortest* path. The difference in how the shortest path is defined:

- BFS: path with the smallest number of edges (assuming the same weight for every edge or no weight).
- Dijkstra: path with the smallest weight along the path.

Consider this undirected connected graph:

We want to find the shortest path from `A`

to `F`

:

- BFS: A->C->E->F or A->B->D->F
- Dijkstra: A->C->E->D->F

Implementation is quite similar, the crucial part of Dijkstra is priority queue usage. I used Python for demonstration:

```
graph = {
'A': {('B', 2), ('C', 1)},
'B': {('A', 2), ('C', 4), ('D', 3)},
'C': {('A', 1), ('B', 4), ('E', 2)},
'E': {('C', 2), ('D', 1), ('F', 4)},
'D': {('B', 3), ('E', 1), ('F', 2)},
'F': {('D', 2), ('E', 4)}
}
def dijkstra(graph, start: str):
result_map = defaultdict(lambda: float('inf'))
result_map[start] = 0
visited = set()
queue = [(0, start)]
while queue:
weight, v = heapq.heappop(queue)
visited.add(v)
for u, w in graph[v]:
if u not in visited:
result_map[u] = min(w + weight, result_map[u])
heapq.heappush(queue, [w + weight, u])
return dict(result_map)
print(dijkstra(graph, 'A'))
```

**Output:**

```
{'A': 0, 'C': 1, 'B': 2, 'E': 3, 'D': 4, 'F': 6}
```

While for BFS ordinary queue is sufficient:

```
graph = {
'A': {'B', 'C'},
'B': {'A', 'C', 'D'},
'C': {'A', 'B', 'E'},
'E': {'C', 'D', 'F'},
'D': {'B', 'E', 'F'},
'F': {'D', 'E'}
}
def bfs(graph, start: str):
result_map = defaultdict(int)
visited = set()
queue = deque([[start, 0]])
while queue:
v, depth = queue.popleft()
visited.add(v)
if v in graph:
result_map[v] = depth
for u in graph[v]:
if u not in visited:
queue.append([u, depth + 1])
visited.add(u)
return dict(result_map)
print(bfs(graph, 'A'))
```

**Output:**

```
{'A': 0, 'C': 1, 'B': 1, 'E': 2, 'D': 2, 'F': 3}
```