## GRAPH Course

# Connected graphs

A graph is connected (`connexe`

) if we only have one connected component (`composante connexe`

). Otherwise, we are calling the graph disconnected (`non connexe`

).

A connected component $C$, is a subgraph of $G$ in which every vertex inside is connected to at least one other vertex inside $C$. A strong component (`composante connexe maximale`

) is a connected component in which we can't add more vertex inside.

**Algorithm**

- pick a vertex
- start with the first connected component $C_i$, $i=0$
- while there are vertex remaining
- for each vertex
- if $C_i$ is empty or this vertex is adjacent to a vertex inside $C_i$
- then: we add it
- else: we go to the next vertex

- i++

- for each vertex

When iterating the vertices, you should do it by looking at the vertex in the edges that incident to a vertex inside your connected component.

## Super-connectivity

A graph is super-connected `Forte connexité/f-connexe`

, if, from any vertex, we can go to any other vertex.

**Algorithm**

- pick a vertex
- mark it "+" and "-"
- mark all vertex we can reach with "+"
- mark all vertex we can be reached from "-"
- you got a first super-connected component (All nodes with "+" and "-")
- if there are remaining edges, restart from one of them

Note: a complete graph is super-connected.

## Terminology

- reduced graph (
`Graphe réduit`

)

If $C_1, C_2, C_3$ are super-connected components, then a graph having the nodes $C_1, C_2, C_3$ is called `Graphe réduit`

. If $A \in C_1$ was adjacent to $B \in C_2$ then we have $C_1$ is adjacent to $C_2$.

- Bridge (
`isthme`

)

An edge that, once removed, will disconnect the graph.

- Articulation point (
`Point d'articulation`

)

A vertex that, once removed, will disconnect the graph.

## Example 1 - Connected graph

Let $G$, the following graph

- What are the connected components?
- Is the graph connected?
- Create a subgraph $G'$ with $\text{{a,b,c,d}}$.
- Is $G'$ connected? And super-connected?

- $C_1={e,f,g}$ and $C_2={a,b,c,d,h,i}$.
Let's apply our connected algorithm

- No, we got more than one connected component
- simply extracting the vertex and their edges

- We got only one component, so the graph is connected. The graph does seem to be super-connected.
Let's apply the super-connected algorithm

The graph is super-connected.

## Example 2 - Transitive closure and Connectivity

Is the following graph $G$ super-connected? Tip: use the transitive closure.

Using Roy-Warshall's algorithm, we got

As you may notice, this is a complete graph $K_{6}$. Since the transitive closure is a complete graph, then $G$ is super-connected.

This wasn't the goal of this example, but here is Roy-Warshall's algorithm

The complete algorithm (text)

picking A- $s=C$

- $p=B$, creating (B,C)? yes
- $p=E$, creating (E,C)? yes
- $p=F$, creating (F,C)? yes
picking B- $s=A$

- $p=C$, creating (C,A)? yes
- $p=F$, creating (F,A)? no
- $p=D$, creating (D,A)? yes
- $s=C$

- $p=F$, creating (F,C)? no
- $p=D$, creating (D,A)? no
picking C- $s=B$

- $p=A$, creating (A,B)? yes
- $p=D$, creating (D,B)? no
- $p=E$, creating (E,B)? yes
- $p=F$, creating (F,B)? no
- $s=E$

- $p=A$, creating (A,E)? yes
- $p=B$, creating (B,E)? yes
- $p=D$, creating (D,E)? yes
- $p=F$, creating (F,E)? yes
picking D- $s=A$

- $p=E$, creating (E,A)? no
- $s=B$

- $p=E$, creating (E,B)? no
- $s=C$

- $p=E$, creating (E,C)? no
- $s=E$
- $s=F$

- $p=E$, creating (E,F)? no
picking E- $s=A$
- $s=A$

- $p=B$, creating (B,A)? no
- $p=C$, creating (C,A) ? yes
- $p=D$, creating (D,A)? no
- $p=F$, creating (F,A)? no
- $s=B$

- $p=A$, creating (A,B)? no
- $s=B$

- $p=C$, creating (C,B)? no
- $p=D$, creating (D,B)? no
- $p=F$, creating (F,B)? no
- $s=C$

- $p=A$, creating (A,C)? no
- $p=B$, creating (B,C)? no
- $s=C$

- $p=D$, creating (D,C)? no
- $p=F$, creating (F,C)? no
- $s=D$

- $p=A$, creating (A,D)? yes
- $p=B$, creating (B,D)? yes
- $p=C$, creating (C,D)? yes
- $s=D$

- $p=F$, creating (F,D)? yes
- $s=F$

- $p=A$, creating (A,F)? yes
- $p=B$, creating (B,F)? yes
- $p=C$, creating (C,F)? yes
- $p=D$, creating (D,F)? no
- $s=F$
picking F

- done