1. Graphical Solution Procedure
Linear Programming
Graphical Solution Procedure

2. Two Variable Linear Programs
When a linear programming model consists of only two variables, a graphical approach can be employed to solve the model.
There are few, if any, real life linear programming models with two variables.
But the graphical illustration of this case helps develop the terminology and approaches for solving larger models.

3. 5-Step Graphical Solution Procedure
Graph the constraints.
The resulting set of possible or feasible points is called the feasible region.
Set the objective function value equal to any number and graph the resulting objective function line.
Move the objective function line parallel to itself until it touches the last point(s) of the feasible region.
This is the optimal solution.
Solve for the values of the variables of the optimal solution.
This involves solving 2 equations in 2 unknowns.
Determin the optimal value of the objective function.
This is done by substituting the variable values into the objective function formula.

4. Graphing the Feasible RegionX2
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2X1 + 1X2 ≤ X1 + 4X2 ≤ X1 + 1X2 ≤ X1 - 1X2 ≤ X1, X2 ≥ 0

5. Graphing the Feasible RegionX2
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2X1 + 1X2 ≤ 1000
2X1 + 1X2 ≤ X1 + 4X2 ≤ X1 + 1X2 ≤ X1 - 1X2 ≤ X1, X2 ≥ 0

6. Graphing the Feasible RegionX2
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2X1 + 1X2 ≤ X1 + 4X2 ≤ X1 + 1X2 ≤ X1 - 1X2 ≤ X1, X2 ≥ 0
2X1 + 1X2 ≤ 1000
3X1 + 4X2 ≤ 2400

7. Graphing the Feasible RegionX2
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2X1 + 1X2 ≤ X1 + 4X2 ≤ X1 + 1X2 ≤ X1 - 1X2 ≤ X1, X2 ≥ 0
2X1 + 1X2 ≤ 1000
1X1 + 1X2 ≤ 700
Redundant Constraint
3X1 + 4X2 ≤ 2400

8. Graphing the Feasible RegionX2
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2X1 + 1X2 ≤ X1 + 4X2 ≤ X1 + 1X2 ≤ X1 - 1X2 ≤ X1, X2 ≥ 0
2X1 + 1X2 ≤ 1000
1X1 + 1X2 ≤ 700
1X1 - 1X2 ≤ 350
Feasible Region
3X1 + 4X2 ≤ 2400

9. Characterization of PointsX2
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(200,700) is an infeasible point
3X1 + 4X2 ≤ 2400
(200,450) is a boundary point
2X1 + 1X2 ≤ 1000
(200,200) is an interior point
(450,100) is an extreme point
1X1 - 1X2 ≤ 350

10. Graphing the Objective FunctionX2
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Set the objective function value equal to any number and graph it.
8X1 + 5X2 = 2000

11. Identifying the Optimal PointX2
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Move the objective function line parallel to itself until it touches the last point of the feasible region.
8X1 + 5X2 = 4360
8X1 + 5X2 = 4000
8X1 + 5X2 = 3000
8X1 + 5X2 = 2000
OPTIMAL POINT

12. Determining the Optimal PointX2
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Solve the 2 equations in 2 unknowns that determines the optimal point.
2X1 + 1X2 = 1000
3X1 + 4X2 = 2400
2X1 + 1X2 = X1 + 4X2 = 2400
Multiply top equation by 4
8X1 + 4X2 = X1 + 4X2 = 2400
Subtract second equation from first
5X = or X1 = 320
Substituting in first equation
2(320) + 1X2 = or X2 = 360
OPTIMAL POINT
(320, 360)

13. Determining the Optimal Objective Function ValueX2
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Substitute x-values into objective function
MAX 8 X X2
(320)
(360) +
= 4360
OPTIMAL POINT
(320, 360)

14. Review 5 Step Graphical Solution Procedure Redundant Constraints
Graph constraints
Graph objective function line
Move the objective function line parallel until it touches the last point of the feasible region
Solve for optimal point
Determin the optimal objective function value
Redundant Constraints
Identification of points
Infeasible
Interior
Boundary
Extreme