Deck 13: Introduction to Optimization Modeling

Binding constraints are constraints that hold as an equality.

Proportionality,additivity,and divisibility are three important properties that LP models possess that distinguish them from general mathematical programming models.

There are generally two steps in solving an optimization problem: model development and optimization.

It is instructive to look at a graphical solution procedure for LP models with three or more decision variables.

Suppose the allowable increase and decrease for shadow price for a constraint are $25 (increase)and $10 (decrease).If the right-hand side of that constraint were to increase by $10,the optimal value of the objective function would change.

When formulating a linear programming spreadsheet model,there is a set of designated cells that play the role of the decision variables.These are called the objective cells.

All linear programming problems should have a unique solution,if they can be solved.

A shadow price indicates how much a company would pay for more of a scarce resource.

Shadow prices are associated with nonbinding constraints,and show the change in the optimal objective function value when the right side of the constraint equation changes by one unit.

Suppose the allowable increase and decrease for an objective coefficient of a decision variable that has a current value of $50 are $25 (increase)and $10 (decrease).If the coefficient were to change from $50 to $60,the optimal value of the objective function would not change.

There are two primary ways to formulate a linear programming problem: the traditional algebraic way and with spreadsheets.

It is often useful to perform sensitivity analysis to see how,or if,the optimal solution to a linear programming problem changes as we change one or more model inputs.

The set of all values of the decision variable cells that satisfy all constraints,not including the nonnegativity constraints,is called the feasible region.

Reduced costs indicate how much the objective coefficient of a decision variable that is currently 0 or at its upper bound must change before that the value of that variable changes.

When formulating a linear programming spreadsheet model,there is one target (objective)cell that contains the value of the objective function.

There is often more than one objective in linear programming problems.

In general,the complete solution of a linear programming problem involves three stages: formulating the model,invoking Solver to find the optimal solution,and performing sensitivity analysis.

The feasible region in a graphical solution of a linear programming problem will appear as some type of polygon,with lines forming all sides.

The divisibility property of LP models simply means that we allow only integer levels of the activities.

Suppose an objective function has the equation: .
Then the slope of the objective function line is 2.

A rolling planning horizon is a multiperiod model where only the decision in the first period is implemented,and then a new multiperiod model is solved in succeeding periods.

Suppose a constraint has this equation: Then the slope of the constraint line is -2.

If an LP model has an unbounded solution,then we must have made a mistake - either we have made an input error or we omitted one or more constraints.

The additivity property of LP models implies that the sum of the contributions from the various activities to a particular constraint equals the total contribution to that constraint.

A feasible solution does not have to satisfy any constraints as long as it is logical.

A decision support system is a user-friendly system where an end user can enter inputs to a model and see outputs,but need not be concerned with technical details.

Infeasibility refers to the situation in which there are no feasible solutions to the LP model.

If a solution to an LP problem satisfies all of the constraints,then it must be feasible.

The proportionality property of LP models means that if the level of any activity is multiplied by a constant factor,then the contribution of this activity to the objective function,or to any of the constraints in which the activity is involved,is multiplied by the same factor.

In determining the optimal solution to a linear programming problem graphically,if the goal is to maximize the objective,we pull the objective function line down until it contacts the feasible region.

The optimal solution to any linear programming model is a corner point of a polygon.

A Solver's sensitivity report shows sensitivity to objective coefficients and right sides of the constraints.

When the proportionality property of LP models is violated,we generally must use non-linear optimization.

A 12-month rolling planning horizon is a single model where the decision in the first period is implemented.

When formulating a linear programming spreadsheet model,we specify the constraints in a Solver dialog box,since Excel does not show the constraints directly.

Nonbinding constraints will always have slack,which is the difference between the two sides of the inequality in the constraint equation.

It helps to ensure that Solver can find a solution to a linear programming problem if the model is well-scaled,that is,if all of the numbers are of roughly the same magnitude.

Linear programming problems can always be formulated algebraically,but not always on a spreadsheet.

Unboundedness refers to the situation in which the LP model has been formulated in such a way that the objective function is unbounded - that is,it can be made as large (for maximization problems)or as small (for minimization problems)as we wish.

A feasible solution is a solution that satisfies all of the constraints.

The value to be optimized in an optimization model (such as profit)is called the objective.