`Find-Set(x)`

is used in disjoint data structures most frequently to implement Minimum Spanning Trees (MST).

If `u`

and `v`

are in the same set, it means that they are already **connected**. If they are already **connected**, then adding *another* connection between them creates a **cycle**.

We can begin analyzing this by saying that all vertices are within their own distinct, single-element sets. When we establish a connection between two vertices e.g. `a-b`

, then we put `a`

and `b`

within the same set. Consequently, we need to determine how they're in the same set; thus, we use `Find-Set(x)`

to determine if they are within the same set (in your case, it's a disjoint forest implementation).

The example you provide does not have a cycle, so I'll add another edge:

## Example

Initially, assume we have a set of vertices `a`

, `b`

, `c`

and `d`

. We want to determine the minimum spanning tree such that there is the minimum number of edges possible to connect all three vertices to the same forest.

Edges available now:
`(a, b)`

, `(c, d)`

, `(b, c)`

, `(d, c)`

(extra edge which is a cycle!)

*This assumes you know the definitions of vertex, edge and forest which are all fundamental graph terms*

Since `a`

and `b`

are currently distinct sets, we can combine them through an algorithm such as `Merge-Set(a, b)`

which places them within the same set: `A=(a, b)`

while there are still `c`

and `d`

that must be connected. *Note here that *`A`

is the name of the set

We can see that `(c, d)`

is also possible; so, we can merge them: `B=(c, d)`

and we also have `(a, b)`

. `B`

is the name of this disjoint set

Now we can merge `A=(a, b)`

and `B=(c, d)`

by knowing that we have edge `(b, c)`

. Since there are multiple elements within the set, we first determine whether the edge is necessary through `Find-Set(x)`

. If `Find-Set(b) == Find-Set(c)`

then we know we have a cycle i.e. if `A == B`

. Fortunately, we do not since `(b, c)`

does not occur within either set `A=(a, b)`

or `B=(c, d)`

. Now we merge them as usual and arrive at our MST which is a set: `A=(a, b, c, d)`

(note that B has been deleted!).

Recall our extra edge which is to be a cycle now. If we attempt to add `(d, c)`

, we see that the set which `d`

and `c`

reside in are the same i.e. `Find-Set(d) == Find-Set(c)`

or `A == A`

since `d`

and `c`

are both in set `A`

. Consequently, we can determine that this edge creates a cycle!