Introduction to Operations ResearchCD-ROM contains: Student version of MPL Modeling System and its solver CPLEX -- MPL tutorial -- Examples from the text modeled in MPL -- Examples from the text modeled in LINGO/LINDO -- Tutorial software -- Excel add-ins: TreePlan, SensIt, RiskSim, and Premium Solver -- Excel spreadsheet formulations and templates. |
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Page 37
... optimal , each with Z = 18 . 8 10 X1 on the line segment connecting ( 2 , 6 ) and ( 4 , 3 ) would be optimal . This case is illustrated in Fig . 3.5 . As in this case , any problem having multiple optimal solutions will have an infi ...
... optimal , each with Z = 18 . 8 10 X1 on the line segment connecting ( 2 , 6 ) and ( 4 , 3 ) would be optimal . This case is illustrated in Fig . 3.5 . As in this case , any problem having multiple optimal solutions will have an infi ...
Page 130
... optimal solution ) that a problem can have more than one optimal solution . This fact was illustrated in Fig . 3.5 by changing the objective function in the Wyndor Glass Co. problem to Z = 3x1 + 2x2 , so that every point on the line ...
... optimal solution ) that a problem can have more than one optimal solution . This fact was illustrated in Fig . 3.5 by changing the objective function in the Wyndor Glass Co. problem to Z = 3x1 + 2x2 , so that every point on the line ...
Page 278
... optimal solution is ( 4,3 ) . When c2 is increased , this solution remains optimal only for c2 ≤ 4. For c2 ≥ 4 , ( 0 , 2 ) becomes optimal ( with a tie at c2 = 4 ) , because of the constraint boundary 3x + 4x2 = 18. When c2 is ...
... optimal solution is ( 4,3 ) . When c2 is increased , this solution remains optimal only for c2 ≤ 4. For c2 ≥ 4 , ( 0 , 2 ) becomes optimal ( with a tie at c2 = 4 ) , because of the constraint boundary 3x + 4x2 = 18. When c2 is ...
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Introduction to Operations Research Frederick S. Hillier,Gerald J. Lieberman No preview available - 2001 |
Common terms and phrases
activity algebraic algorithm allowable range artificial variables b₂ basic solution c₁ c₂ changes coefficients column Consider the following cost Courseware CPLEX decision variables dual problem dual simplex method dynamic programming entering basic variable estimates example feasible region feasible solutions final simplex tableau final tableau following problem formulation functional constraints Gaussian elimination given goal programming graphical identify increase initial BF solution integer iteration leaving basic variable linear programming model linear programming problem LINGO LP relaxation lution Maximize Z maximum flow problem Minimize needed node nonbasic variables nonnegativity constraints objective function obtained optimal solution optimality test parameters path plant presented in Sec primal problem Prob procedure range to stay resource right-hand sides sensitivity analysis shadow prices shown slack variables solve the model Solver spreadsheet step subproblem surplus variables Table tion unit profit values weeks Wyndor Glass x₁ zero