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The pseudo code for dynamic programming is showing below. Note we use bottom up to fill up <math>R</math> and <math>L</math>. | The pseudo code for dynamic programming is showing below. Note we use bottom up to fill up <math>R</math> and <math>L</math>. | ||
− | [[File:Dynamic.png| | + | [[File:Dynamic.png|600px|Pseudo code for dynamic programming]] |
In the end of the program, <math>R[n]</math> will be the maximum revenue, and L[n], L[L[n]], ... will be the indices of locations to choose. | In the end of the program, <math>R[n]</math> will be the maximum revenue, and L[n], L[L[n]], ... will be the indices of locations to choose. |
Revision as of 18:08, 20 July 2017
Computer Engineering(CE)
Question 1: Algorithms
August 2013
Solution 1
This problem can be solved using dynamic programming. For each docks $ x_i $, compute the revenue from $ x_1 $ to $ x_i $, if $ x_i $ is selected, and the remaining docks $ x_{i+1} $ to $ x_n $, if $ x_i $ is not selected.
$ R[i] $: denote the total revenue using only sites $ x_1, \dots , x_i $.
$ L[i] $: denote $ i $ with the greatest value such that $ x_i $ is used for the solution in $ R[i] $.
Initially, $ L[<=0]=0 $, $ R[<=0]=0 $, $ x_0 = -\infty $, $ r_0=0 $. The pseudo code for dynamic programming is showing below. Note we use bottom up to fill up $ R $ and $ L $.
In the end of the program, $ R[n] $ will be the maximum revenue, and L[n], L[L[n]], ... will be the indices of locations to choose.