# Solving addition chain problems using dynamic programming

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:

1. The first element of the sequence is 1
2. Each of the successive elements is the sum of any two preceding elements (adding a single element to itself is also permissible)
3. 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 sub-problems. 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?

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There is no known algorithm which can calculate a minimal addition chain for a given number with any guarantees of reasonable timing or small memory usage. However, several techniques to calculate relatively short chains exist. One very well known technique to calculate relatively short addition chains is the binary method, similar to exponentiation by squaring. Other well-known methods are the factor method and window method.

New Methods For Generating Short Addition Chains

http://it29.it.k.u-tokyo.ac.jp/pdfs/E83-A-1-60.pdf

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