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blog/algorithms/10-graphs/2022-04-30-bfs-tree.md
Matej Focko e1dea0cdbc
feat: don't reference FI MU subjects by their codes 
Signed-off-by: Matej Focko <mfocko@redhat.com>
2023-11-24 16:30:23 +01:00

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---
id: bfs-tree
title: Distance boundaries from BFS tree on undirected graphs
description: |
Short explanation of distance boundaries deduced from a BFS tree.
tags:
- graphs
- bfs
last_update:
date: 2022-04-30
---
## Introduction
As we have talked on the seminar, if we construct from some vertex $u$ BFS tree on an undirected graph, we can obtain:
- lower bound of length of the shortest path between 2 vertices from the _height difference_
- upper bound of length of the shortest path between 2 vertices from the _path through the root_
## Lower bound
Consider the following graph:
![](/files/algorithms/graphs/bfs-tree/bfs_graph_light.svg#gh-light-mode-only)
![](/files/algorithms/graphs/bfs-tree/bfs_graph_dark.svg#gh-dark-mode-only)
We run BFS from the vertex $a$ and obtain the following BFS tree:
![](/files/algorithms/graphs/bfs-tree/bfs_tree_light.svg#gh-light-mode-only)
![](/files/algorithms/graphs/bfs-tree/bfs_tree_dark.svg#gh-dark-mode-only)
Let's consider pair of vertices $e$ and $h$. For them we can safely lay, from the BFS tree, following properties:
- lower bound: $2$
- upper bound: $4$
By having a look at the graph we started from, we can see that we have a path $e, j, h$ that has a length 2. Apart from that we can also notice there is another path from $e$ to $h$ and that is $e, a, c, i, d, h$. And that path has a length of $5$. Doesn't this break our statements at the beginning? (_I'm leaving that as an exercise ;)_)
## Proof by contradiction
Let's keep the same graph, but break the lower bound, i.e. I have gotten a lower bound $2$, but “there must be a shorter path”! ;)
Now the more important question, is there a shorter path in that graph? The answer is no, there's no shorter path than the one with length $2$. So what can we do about it? We'll add an edge to have a shorter path. Now we have gotten a lower bound of $2$, which means the only shorter path we can construct has $1$ edge and that is $e, h$ (no intermediary vertices). Let's do this!
![](/files/algorithms/graphs/bfs-tree/bfs_graph_with_additional_edge_light.svg#gh-light-mode-only)
![](/files/algorithms/graphs/bfs-tree/bfs_graph_with_additional_edge_dark.svg#gh-dark-mode-only)
Okay, so we have a graph that breaks the rule we have laid. However, we need to run BFS to obtain the new BFS tree, since we have changed the graph.
:::tip
Do we need to run BFS after **every** change?
­I am leaving that as an exercise ;)
:::
![](/files/algorithms/graphs/bfs-tree/bfs_tree_with_additional_edge_light.svg#gh-light-mode-only)
![](/files/algorithms/graphs/bfs-tree/bfs_tree_with_additional_edge_dark.svg#gh-dark-mode-only)
Oops, we have gotten a new BFS tree, that has a height difference of 1.
:::tip
Try to think about a way this can be generalized for shortening of minimal length 3 to minimal length 2 ;)
:::
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