Eight step procedures: Difference between revisions
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'''Step 1: Specify the stages of the problem''' <br /> | '''Step 1: Specify the stages of the problem''' <br /> | ||
• The stages of a dynamic programming problem can be defined as points where decisions are made. These are often denoted with the variable n. <br /> | • The stages of a dynamic programming problem can be defined as points where decisions are made. These are often denoted with the variable n. <br /> | ||
Step 2: Specify the states for each stage <br /> | <br /> | ||
'''Step 2: Specify the states for each stage''' <br /> | |||
• The states of a problem are defined as the knowledge necessary to make a decision, or s. We set C equal to the maximum value of s. <br /> | • The states of a problem are defined as the knowledge necessary to make a decision, or s. We set C equal to the maximum value of s. <br /> | ||
Step 3: Specify the allowable actions for each state in each stage <br /> | <br /> | ||
'''Step 3: Specify the allowable actions for each state in each stage''' <br /> | |||
• This can be defined as: <br /> | • This can be defined as: <br /> | ||
o Un(s) or j = 0,1,…,min{a[n], floor(s/w[n])} <br /> | o Un(s) or j = 0,1,…,min{a[n], floor(s/w[n])} <br /> | ||
Step 4: Describe the optimization function using an English-language description. <br /> | <br /> | ||
'''Step 4: Describe the optimization function using an English-language description.''' <br /> | |||
• In this sentence, we describe the optimization function for each state, or s, and each stage, or n. This can also be called F*n(s) <br /> | • In this sentence, we describe the optimization function for each state, or s, and each stage, or n. This can also be called F*n(s) <br /> | ||
Step 5: Define the boundary conditions <br /> | <br /> | ||
'''Step 5: Define the boundary conditions''' <br /> | |||
• This helps create a starting point to finding a solution to the problem. First, we set f*n+1(s) = 0 for all values of s. Here, we can note that s = 0,…,C <br /> | • This helps create a starting point to finding a solution to the problem. First, we set f*n+1(s) = 0 for all values of s. Here, we can note that s = 0,…,C <br /> | ||
Step 6: Define the recurrence relation <br /> | <br /> | ||
'''Step 6: Define the recurrence relation''' <br /> | |||
• During this step, we make an allowable decision involving j items for the remaining capacity s for items n. We can write this statement as: <br /> | • During this step, we make an allowable decision involving j items for the remaining capacity s for items n. We can write this statement as: <br /> | ||
o f*n(s) = max j=0,1,…,min{a[n], floor(s/w[n]0} {b[n,j]+f*n+a(s-j*w[n])} <br /> | o f*n(s) = max j=0,1,…,min{a[n], floor(s/w[n]0} {b[n,j]+f*n+a(s-j*w[n])} <br /> | ||
Step 7: Compute the optimal value from the bottom-up <br /> | <br /> | ||
'''Step 7: Compute the optimal value from the bottom-up''' <br /> | |||
• In this step, a table is made <br /> | • In this step, a table is made <br /> | ||
Revision as of 18:35, 20 November 2020
Author: Eljona Pushaj, Diana Bogdanowich, Stephanie Keomany
Steward: Fengqi You
Introduction
Theory, Methodology, and/or Algorithmic Discussion
Definition
To solve a problem using the 8-step procedure, one must follow the following steps:
Step 1: Specify the stages of the problem
• The stages of a dynamic programming problem can be defined as points where decisions are made. These are often denoted with the variable n.
Step 2: Specify the states for each stage
• The states of a problem are defined as the knowledge necessary to make a decision, or s. We set C equal to the maximum value of s.
Step 3: Specify the allowable actions for each state in each stage
• This can be defined as:
o Un(s) or j = 0,1,…,min{a[n], floor(s/w[n])}
Step 4: Describe the optimization function using an English-language description.
• In this sentence, we describe the optimization function for each state, or s, and each stage, or n. This can also be called F*n(s)
Step 5: Define the boundary conditions
• This helps create a starting point to finding a solution to the problem. First, we set f*n+1(s) = 0 for all values of s. Here, we can note that s = 0,…,C
Step 6: Define the recurrence relation
• During this step, we make an allowable decision involving j items for the remaining capacity s for items n. We can write this statement as:
o f*n(s) = max j=0,1,…,min{a[n], floor(s/w[n]0} {b[n,j]+f*n+a(s-j*w[n])}
Step 7: Compute the optimal value from the bottom-up
• In this step, a table is made