You are given a positive integer A. The goal is to construct the shortest possible sequence of integers ending with A, using the following rules:
 The first element of the sequence is 1
 Each of the successive elements is the sum of any two preceding elements (adding a single element to itself is also permissible)
 Each element is larger than all the preceding elements; that is, the sequence is increasing.
For example, for A = 42, a possible solutions is [1, 2, 3, 6, 12, 24, 30, 42]. Another possible solution is [1, 2, 4, 5, 8, 16, 21, 42].
After reading the problem statement, the first thing that came to my mind is Dynamic Programming
, hence I expressed the above as Search Problem and try to write a recursive solution for it.
Search Space:
1

2
/ \
/ \
3 4
/\ /\
/  \ 5 6 8
/  \
4 5 6
/ \
5 6 7 8
Now as we can see that 4 occurs in two places, but in both the cases the children of 4 are different, as in one case sequence_so_far is [1, 2, 4] and in other case it is [1, 2, 3, 4], hence we cannot say that we have overlapping subproblems. Is there any way to apply Dynamic Programming to the above problem? Or I am wrong in judging that it can be solve using DP?