I was going through the longest common sub sequence problem in the INTRODUCTION TO ALGORITHMS by CLRS.But i was unable to understand the thought process behind it. Most other problems explained were pretty intuitive and am confident that i can solve similar problems in the future but i am unable to visualize the LCS problem as i do not understand the logic behind how the optimal substructure is determined.

the book gives the following explanation for the optimal sub structure

**Theorem 15.1 (Optimal substructure of an LCS)

Let X == and Y == be sequences, and let Z =
be any LCS of X and Y.
1. If `xm = yn`

,then `zk = xm = yn`

and `Zk−1`

is an LCS of `Xm−1`

and `Yn−1`

.
2. If `xm != yn`

,then `zk = xm`

implies that `Z`

is an LCS of `Xm−1`

and `Y`

.
3. If `xm != yn`

,then `zk = yn`

implies that `Z`

is an LCS of `X`

and `Yn−1`

.
Proof (1) If `zk != xm`

, then we could append `xm = yn`

to `Z`

to obtain a common
subsequence of `X`

and `Y`

of length `k + 1`

, contradicting the supposition that `Z`

is
a longest common subsequence of `X`

and `Y`

. Thus, we must have `zk = xm = yn`

.

Now, the preﬁx `Zk−1`

is a `length-(k − 1)`

common subsequence of `Xm−1`

and `Yn−1`

.
We wish to show that it is an LCS. Suppose for the purpose of contradiction that
there is a common subsequence `W`

of `Xm−1`

and `Yn−1`

with length greater than `k−1`

.
Then, appending `xm = yn`

to `W`

produces a common subsequence of `X`

and `Y`

whose length is greater than `k`

, which is a contradiction.

(2) If `zk != xm`

,then `Z`

is a common subsequence of `Xm−1`

and `Y`

. If there were a
common subsequence `W`

of `Xm−1`

and `Y`

with length greater than `k`

,then `W`

would
also be a common subsequence of `Xm`

and `Y`

, contradicting the assumption that `Z`

is an LCS of `X`

and `Y`

.

(3) The proof is symmetric to (2).**

The proof is clear but i can't see how they came up with the optimal substructure. Can someone help?