A few lemmas/facts before we get started with proof.

- T is a tree so there is exactly 1 path between any 2 pair of vertices.
- If S--D is the diameter then a BFS with source as S (or D) will end up giving D (or S) the largest distance. (
*By definition of diameter*)

Also lets define |XY| to be the length of the path X--Y.

Define |XX| = 0.

Let A be the random node selected by the algorithm.
After Step 2 let the furthest node got be P.
If P is either S or D then using *Lemma 2* we are done. So we must show that P has to be either S or D.

Claim : If S--D is the diameter, then P is either S or D.

Proof: I am going to prove the above by proving the Contrapositive. The proof is for a tree with a unique diameter but it should work with minor changes (mostly the equalities) for non-unique diameters too.

**If P is neither S nor D then S--D is not the diameter.**

Assume P is neither S nor D.

**Case 1: The Path A--P intersects S--D**

Let the point of intersection be K. We know that BFS marked P as the farthest node from A and from *Lemma 1*.

|AP| > |AS|
|AK| + |KP| > |AK| + |KS|

Therefore we get |KP| > |KS|.

Similarly |KP| > |KD|.

Now we consider the path SP

|SP| = |SK| + |KP|
|SP| > |SK| + |KD|
|SP| > |SD|

So SP is longer than the diameter which means SD is NOT the diameter.

**Case 2:The Path A--P does NOT intersects S--D**

Now we know BFS marked P as the farthest node. So we have

|AP| > |AD|
|AP| > |AS|

We can write |AD| = |AK| + |KD| where K is one of the vertices in the diameter (including S and D). Similarly |AS| = |AK| + |KS|.

Without loss of generality assume |AD|>=|AS|

|AK| + |KD| >= |AK| + |KS|
|KD| >= |KS|

Now consider the path PD

|PD| = |AP| + |AD|
|PD| = |AP| + |AK| + |KD|
|PD| > |AP| + |KD| (|AK| > 0 since A cannot be on the diameter)
|PD| > |KD| + |KD| (|AP| > |KD|)
|PD| > |SK| + |KD| (|KD| >= |KS|)
|PD| > |SD|

So SD is not the diameter and hence the claim.