I think unkulunkulu's answer is pretty complete, but given JMSA seems unsatisfied, I'll make another attempt.

Let's start not with the path matrix, but with the **adjacency matrix**. The adjacency matrix is the standard representation of a graph. If **adj** is the adjacency matrix for some graph **G**, then **adj[i][j]** == **1** if vertex **i** is adjacent to vertex **j** (i.e. there is an edge from **i** to **j**), and **0** otherwise. In other words, **adj[i][j] == 1** if and only if we can get from vertex **i** to vertex **j** in *one* "step".

Now, let's define another matrix which I'll call **adj2**: **adj2[i][j] == 1** if and only if we can get from vertex **i** to vertex **j** in *two* steps or less. You might call it a "two-step adjacency" matrix. The important thing is that **adj2** can be defined in terms of **adj**:

```
def adj2(i,j):
if adj(i,j) == 1:
return 1
else:
for k in range(0,n): # where n is the number of vertices in G
if adj(i,k) == 1 and adj(k,j) == 1:
return 1
return 0
```

That is, **adj2[i][j]** is **1** if **i** is adjacent to **j** (i.e. **adj[i][j]** == **1**) or if there exists some other vertex **k** such that you can step from **i** to **k** and then from **k** to **j** (i.e. **adj[i][j] == 1 and adj[k][j] == 1**).

As you can imagine, you can use the same logic to define a "three-step" adjacency matrix **adj3**, **adj4**, **adj5**, and so on. If you go on long enough (e.g. to **adjn**, where **n** is the number of vertices in the graph), you get a matrix that tells you whether there's a path of *any length* from vertex **i** to vertex **j**. This, of course, would also be the graph's path matrix: **adjn[i][j] == path[i][j] for all i, j**. (Note: Don't confuse path matrix with distance matrix.)

A mathematician would say that **path[i][j]** is the transitive closure of **adj[i][j]** on the graph **G**.

Transitive closures exist independently from graph theory; **adj** is not the only thing with a transitive closure. Roughly speaking, all functions (in the programming sense) that take two arguments and return a Boolean value have a transitive closure.

The equality (==) and inequality (<, >, <=, >=) operators are familiar examples of such functions. These differ from **adj**, however, in that they are themselves *transitive*. "**f(i,j)** is transitive" means that if **f(i,j) == true**, and **f(j,k) == true**, then **f(i, k) == true**. You know that this property is true of, say, the "less than" relation: from **a < b** and **b < c**, you can infer that **a < c**. The transitive closure of a transitive function **f** is just **f**.

**adj** is not *generally* transitive. Consider the graph:

```
v1---v2---v3
```

In this graph, **adj** might represent the function **busBetween(city1, city2)**. Here, there's a bus you can take from v1 to v2 (**adj[1][2] == 1**) and a bus from v2 to v3 (**adj[2][3] == 1**), but there's no bus from v1 directly to v3 (**adj[1][2] == 0**). There is a bus-path from v1 to v3, but v1 and v3 are not bus-adjacent. For this graph, **adj** is not transitive, so **path**, which is the transitive closure of **adj**, is different from **adj**.

If we add an edge between v1 and v3,

```
v1---v2---v3
\ /
\----/
```

then **adj** becomes transitive: In every possible case, **adj[i][j] == 1** and **adj[j][k] == 1** implies **adj[i][k] == 1**. For this graph, **path** and **adj** are the same. That the graph is undirected corresponds to the "symmetry" property. If we added loops to each vertex so that v1, v2, and v3 were each adjacent to themselves, the resulting graph would be transitive, symmetric, and "reflexive", and could be said to represent equality (==) over the set {1,2,3}.

This begins to illustrate how graphs can represent different functions, and how properties of the function are reflected in properties of the graph. In general, if you let **adj** represent some function **f**, then **path** is the transitive closure of **f**.

For a formal definition of transitive closures, I refer you to Wikipedia. It isn't a hard concept once you understand all the math jargon.