Let \(F_A\) and \(F_B\) be the number of *"A"* (auburn) shards and the number of *"B"* (black) shards, respectively.

We can observe that every time shards are fused \(F_A\) and \(F_B\) each decrease by \(1\). One implication of this is that total number of shards \(F_A + F_B\) decreases by \(2\) each time. Since \(N\) is initially a positive odd integer, this means that the sequence of shards will always be reduced to a single shard after enough fusing operations, as long as they can all be performed safely. A more interesting implication is that \(F_A - F_B\) remains constant between operations. Since \(F_A - F_B\) must be equal to either \(1\) or \(-1\) when there's one shard remaining, we must also have \(|F_A - F_B| = 1\) in the initial sequence in order for that final state to be achievable.

So far, we've shown that the answer must be *"N"* if \(|F_A - F_B| \neq 1\). The remaining question is whether the answer is always *"Y"* if \(|F_A - F_B| = 1\). The only way it could be *"N"* is if it were impossible to perform a fusing operation at any point while there are three or more shards. This is only impossible if all shards are the same colour (as there must otherwise be at least one consecutive triple of shards not all sharing the same colour), which cannot ever be the case if \(N \geq 3\) and \(|F_A - F_B| = 1\) (as we must have \(F_A \geq 1\) and \(F_B \geq 1\)).

Therefore, we have only to loop over the shards in \(O(N)\) time to compute \(F_A\) and \(F_B\), and then check whether or not \(|F_A - F_B| = 1\).