# Continuous version of rod cutting

This might not be a question for this forum, but it is an attempt to extend an idea from Computer Science.. the dynamic programming based solution of the rod cutting problem (given a rod of an integral length and an array of prices for each integral value of the length, find the optimal cuts that maximize profit). I asked a question about the implementation of the rod cutting problem here yesterday. But thinking about it made me wonder.. what if we were not constrained to cut the rod at integral values, but could cut it any where we liked (fractional lengths are possible). Further, lets say that instead of a table of prices corresponding to the integral lengths, we are given a continuous (monotonically increasing, tapering) function that represents the value of the rod at different lengths. For example, for a rod of length 1, the value function might be given by the CDF of a beta distribution. Now, we want to find the number of cuts that we should make and at what values to optimize the total value. Has any one heard of such a problem (I couldn't find any thing online)?

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you might find more people who know the answer here: cstheory.stackexchange.com –  Ciro Santilli 六四事件 法轮功 纳米比亚 威视 Aug 10 '13 at 8:16
I suppose you count not find anything about this on-line because the problem seems to be trivial (but I might be wrong). I do not have a proof for this, but what about recursively cutting the rod in half such that the sum of the values of the parts is optimal, till you cannot make any improvement? –  proskor Aug 10 '13 at 8:39
But this is an extension of when the problem is discrete. When it is discrete, the answer is non trivial and is found through dynamic programming. It we just make one of those discrete problems with a non trivial solution continuous by "joining the dots" for example, making a continuous function pass through each point of the price array, we get some thing non trivial. In the continuous version, we have even more freedom. So it doesn't seem like the answer will be trivial. –  Rohit Pandey Aug 10 '13 at 15:35
You might be right in this particular case, but your argument is not correct in general. For example, making knapsack continuous renders it trivial, especially since we get more freedom. –  proskor Aug 10 '13 at 17:12
Yeah, I actually got a good answer to this here - scicomp.stackexchange.com/questions/8208/… You were mostly right, but there is an interesting general case. –  Rohit Pandey Aug 10 '13 at 23:19