Linear Programming

Sensitivity Analysis and more...

last updated Monday, April 1, 2024
#Linear Programming #Problem Formulation Checklist

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John Burson

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CONTENTS

Linear programming is a quantitative analysis technique for optimizing an objective function given constraints. As the name implies, the functions must be linear for linear programming techniques.

Problem Formulation Checklist

The objective function and constraints are formulated using information extracted from the problem statement. The following checklist helps minimize the risk of errors in problem formulation.

1. Every number in the problem statement should either be implemented in the formulation or rejected as irrelevant, e.g., sunk costs.
2. Don't forget any initial conditions, e.g., initial staff at the beginning of the first staffing period.
3. Ensure every variable in the objective function is listed somewhere in the constraints.
4. Ensure that any non-negativity constraints are listed.
5. Ensure that binary integer variables are restricted to 0,1.
   For example, Y ∈ {0,1}
6. For good form, move all variables to the left-hand side of the equation, writing them in the order of their subscripts.

 Sensitivity Analysis

While problems may be modeled using deterministic, objective functions, in the real world, there is variation. A sensitivity analysis can be performed to determine the sensitivity of the solution to changes in parameters.

Microsoft Excel can generate a sensitivity report in two parts - a changing cells report and a constraints report.

Changing Cells (Adjustable Cells)

Cell

Name

Final Value

Reduced Cost

Objective Coefficient

Allowable Increase

Allowable Decrease

For the Changing Cells report, the allowable increase and decrease refers to how much the objective function decision variable coefficient can change without changing the values of any decision variable. However, the objective function value will have to change if a coefficient changes and the corresponding decision variable does not change. Note, though, that multiplying each term in the objective function by a constant does not change the values of the decision variables.

The 100% rule can be used to determine if a change in multiple objective function coefficients will change the values of the decision variables. Under this rule, any combination of changes can occur without a change in the solution as long as the total percentage deviation from the coordinate extremes does not exceed 100%. However, the objective value would change since the objective coefficients are changing.

For this analysis, the decision variable coefficient is the effective number multiplied by the decision variable when the objective function is simplified so that each decision variable appears once.

Reduced Cost is how much more attractive the variable's coefficient in the objective function must be before the variable is worth using. Ignore the sign reported by Excel.

Constraints

Cell

Name

Final Value

Shadow Price

Constraint R.H. Side

Allowable Increase

Allowable Decrease

The shadow price is the amount that the objective function value would change if the named constraint changed by one unit. The shadow price is valid up to the allowable increase or decrease in the constraint. The shadow price after the constraint is changed by the entire allowable amount is unknown. Still, it is always less favorable than the reported value due to the law of diminishing returns.

To determine if a constraint is binding, compare the Final Value with the Constraint R.H. Side. If a constraint is non-binding, its shadow price is zero.

Linearity from Non-Linear Problems

Many problems that initially may be non-linear may be made linear by careful formulation. For example, one can avoid using the inequality ≠. For binary integer variables, X + Y ≠ 1 is the same as saying X = Y.

Binary Variables

When relating continuous decision variables to binary switch variables, the following form is often useful:

Continuous variable expression  <  (some large number) (binary variable)

Simulation

Linear programming techniques assume certainty and, by themselves, do not deal well with significant randomness. The following is one possible procedure for maximizing or minimizing some objective function that contains random variables.

1. Express the objective function in terms of the decision variable.
2. Define a search range and incremental search value for the decision variable, possibly using problem information to reduce the search range.
3. Simulate each incremental value of the decision variable using a Monte Carlo simulator such as Crystal Ball.
4. Compare the mean expected values of the objective function and their confidence intervals, possibly using statistical hypothesis testing to identify the best solution.

Confidence Intervals

95% confidence intervals:   +/- 1.96 sigma

90% confidence intervals:   +/- 1.645 sigma

Useful Functions

MIN(x,y) or MAX(x,y)	x,y can be any variable (possibly a random variable), expression, or number. Applications include revenue calculations that might be limited by either demand or production quantity.
~N(μ = x, σ = y)	normal distribution with mean x, std dev. y; directly to the right of a random variable
~U[x,y]	uniform distribution with min x, max y; directly to right of random variable

 
 
 

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