# Recursive solution to Dynamic Programming [duplicate]

Possible Duplicate:
Dynamic Programming and Knapsack Application

I have been trying to understand Dynamic Programming but with each new problem I get a bit confused over how to write recursion for it.

Take the following problem: There is an L × H metal sheet which can be cut by a machine into two pieces either vertically or horizontally.Both L, H are integral and the cuts also happen along integral values.There are n rectangular patterns l(i) × h(i) , i ≤ n (l , h are also integral) where the i-th pattern has proﬁt c(i). Design an eﬃcient algorithm to cut the sheet in a way so as to maximize the total proﬁt.

Now I think for solving it we would create a table of LxH (which would be filled diaganally). But how do we form a recursion for solving this problem ?

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You should start with a recursive O(2^n) solution and look at how to optimize it into a polynomial solution, rather than doing the opposite. –  jli Oct 5 '12 at 18:11
@jli how do I start approaching this problem ? –  user978278 Oct 5 '12 at 18:14
Same question here –  Haile Oct 5 '12 at 18:18
A dynamic programming problem can be solved using recursion by definition, as each instance that's not a base case can be solved using dynamic programming and some extra steps. What makes this different from recursion is not clear. Are you sure this isn't homework? –  Marc van Dongen Oct 5 '12 at 21:49

## marked as duplicate by interjay, Pops♦, Argalatyr, ks1322, hirschhornsalzOct 6 '12 at 11:47

I'd try something like for every T(L, H), verify the best alternative between:

• collect the profit right away
• cut every possible way horizontally
• cut every possible way vertically

Something like:

``````T(L, H) = max(
c(L, H),
T(i, H)+T(L-i, H), // 0<i<L
T(L, i)+T(L, H-i)  // 0<i<H
)
``````
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I don't understand why do you really want to use recursion while you have a dp-relation. Backtracking-recursion is often very-inefficient as its complexity is usually O(2^N) or higher.

However, those exponential algorithms are much like this:

``````function rec(state)
if state = end
return
Choose the current element
rec(state + 1)
Don't choose the current element
rec(state + 1)
``````

In your case this maybe something like this brute-force:

``````  function rec(rect r)
if r is empty
return 0
Max = 0
for i = 1 to r.width
for j = 1 to r.hight
rect g = cut(r, i, j)
Max = max(Max, profit(g) + rec(r - g))
return Max
``````
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