# Dynamic Programming recursive formula

I am trying to go over some notes and examples of dynamic programming, and I have having some difficulty figuring out how it all works. I will post the question, and then what I am having difficulty with:

Given a sequence of points p1= (x1,y1),...,pn=(xn,yn) sorted from left to right (ie, x1 < x2 < ... < xn) and a number k between 1 and n, find a polygonal chain from p1 to pn with k edges that goes from left to right, minimizing the sum of the vertical distances of the points to the chain. Design dynamic programming algorithm that solves the problem in O(n^3) time. Set the subproblems, give all base cases necessary, calculate recursive formula, and write pseudocode for the algorithm. Also a function f(a,b) is defined for us to use in calculating the vertical difference, so I dont have to worry about implementing that. I can just use it as f(a,b)

I believe that the subproblems should be divided as such:

C[i,j] = polygonal chain from p1 to pi with j edges, minimizing the sum of vertical distances.

And then the answer would be: C[n,k]

Base case: C[i,0] = 0

And now I am having some difficulty coming up with the recursive formula. My first question, have I broken the subproblems up correctly? The question gives a hint that makes it seem like I did, but I am not 100% sure. If I am, any hints on how to proceed with deriving the recursive formula?

Thanks for any help guys.

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Instead of having `C(i, j)` mean any chain from 1 to i with j edges, make it mean specifically "A chain that ends in i". Then, to determine the answer for `C(i, j)` you just have to try all the possibilities for where the last edge started.
Then the answer can be the optimal of all `C(i, k)`.