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The Simplex Algorithm

The Simplex Algorithm. An approach to optimization problems for linear real arithmetic constraints. Content. Optimization – what is that? The Simplex Algorithm – background Simplex form Basic feasible solved form / basic feasible solution The algorithm Initial basic feasible solved form.

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The Simplex Algorithm

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  1. The Simplex Algorithm An approach to optimization problems for linear real arithmetic constraints

  2. Content • Optimization – what is that? • The Simplex Algorithm – background • Simplex form • Basic feasible solved form / basic feasible solution • The algorithm • Initial basic feasible solved form The Simplex Algorithm

  3. Content • Optimization – what is that? • The Simplex Algorithm – background • Simplex form • Basic feasible solved form / basic feasible solution • The algorithm • Initial basic feasible solved form The Simplex Algorithm

  4. Optimization – what is that? • In general • Optimization problem (C,f) with constraint C and objective function f e.g. The Simplex Algorithm

  5. Optimization – what is that? Objective function f: • expression over variables V in constraint C • evaluates to a real number • e.g. The Simplex Algorithm

  6. Optimization – what is that? a valuation θ (substituting variables by values): solution of objective function using θ: The Simplex Algorithm

  7. Optimization – what is that? preferred valuations: • valuation θ is preferred to valuation θ', if f(θ) < f(θ') optimal solution: • θ is optimal, if f(θ) < f(θ') for all solutions θ' θ (there is no solution that is preferred to θ) The Simplex Algorithm

  8. Optimization – what is that? Do all problems have an optimal solution? The Simplex Algorithm

  9. Optimization Example An optimization problem Find the closest point to the origin satisfying the C. Some solutions and f value Optimal solution

  10. Content • Optimization – what is that? • The Simplex Algorithm – background • Simplex form • Basic feasible solved form / basic feasible solution • The algorithm • Initial basic feasible solved form The Simplex Algorithm

  11. Background • George Dantzig • born 8.11.1914, Portland • invented "Simplex Method of Optimisation" in 1947 • this grew out of his work with the USAF The Simplex Algorithm

  12. Background • originates from planning tasks: • plans or schedules for training • logistical supply • deployment of men • has in practice usually polynomial cost The Simplex Algorithm

  13. Quotes Eugene Lawler (1980): [Linear programming] is used to allocate resources, plan production, schedule workers, plan investment portfolios and formulate marketing (and military) strategies. The versatility and economic impact of linear programming in today's industrial world is truly awesome. The Simplex Algorithm

  14. Quotes Dantzig I: The tremendous power of the simplex method is a constant surprise to me. Dantzig II: ... it is interesting to note that the original problem that started my research is still outstanding - namely the problem of planning or scheduling dynamically over time, particularly planning dynamically under uncertainty. If such a problem could be successfully solved it could eventually through better planning contribute to the well- being and stability of the world. The Simplex Algorithm

  15. Content • Optimization – what is that? • The Simplex Algorithm – background • Simplex form • Basic feasible solved form / basic feasible solution • The algorithm • Initial basic feasible solved form The Simplex Algorithm

  16. The example An optimization problem showing contours of the objective function

  17. Simplex form • (C,f) is in simplex form, if C has the form • CE is a conjunction of linear arithmetic equations • CI is a term that constrains all variables in C to be 0 The Simplex Algorithm

  18. Simplex form allowed conversions to get simplex form: • X not constrained to be non-negative: • inequality e  r (e=expression and r=number) The Simplex Algorithm

  19. An equivalent simplex form is: The example An optimization problem showing contours of the objective function

  20. Content • Optimization – what is that? • The Simplex Algorithm – background • Simplex form • Basic feasible solved form / basic feasible solution • The algorithm • Initial basic feasible solved form The Simplex Algorithm

  21. Basic feasible solved form feasible = practicable, able to be carried out (durchführbar, anwendbar) • a simplex form optimization problem is in basic feasible solved form, if all equations in CE (of the simplex form) have the form: The Simplex Algorithm

  22. Basic feasible solved form • X0 is called basic variable, does not occur anywhere else (neither in objective function) • X1...n are parameters • b, a1...n are constants • b0 The Simplex Algorithm

  23. Basic feasible solution • corresponding basic feasible solution to a basic feasible solved form: • setting each X1...n = 0 The Simplex Algorithm

  24. Basic feasible solved form: The example An equivalent simplex form is: An optimization problem showing contours of the objective function

  25. Content • Optimization – what is that? • The Simplex Algorithm – background • Simplex form • Basic feasible solved form / basic feasible solution • The algorithm • Initial basic feasible solved form The Simplex Algorithm

  26. The algorithm • idea: optimal solution has to be in one of the vertices • so: go from one vertex to the preferred next vertex • end: if there is no preferred vertex, the actual has to be the optimal solution The Simplex Algorithm

  27. The algorithm in other words: • take a basic feasible solved form • look for an "adjacent" basic feasible solved form whose basic feasible solution decreases the value of the objective function • if there is no such adjacent basic feasible solved form, then the optimum has been found The Simplex Algorithm

  28. The algorithm • adjacent  just one single pivot • pivoting  move one variable out of basic variables ( exit variable) and another in ( entry variable) The Simplex Algorithm

  29. The algorithm Problem: Which variables should be exiting resp. entering? • Entering Variable: • choose one YJ with dJ<0 •  pivoting on this YJ can only decrease f (see next slide) • no such YJ optimum has been found The Simplex Algorithm

  30. Why pivoting on a Yj with dj<0 decreases objective function f • looking at the basic feasible solution (bfs) every parametric variable (Yj) is set to 0 • pivoting on such a variable (var. becomes basic) leads to an increase of this variable in the bfs: Yj≥0  a Yj with negative dj decreases f The Simplex Algorithm

  31. The algorithm Exiting variable: • we have to maintain basic feasible solved form  all bi's have to be 0  choose a Xi so that –bI/aIJ is a minimum of: • M={Ø}  optimization problem unbounded The Simplex Algorithm

  32. Simplex Example Choose variable Z, the 2nd eqn is only one with neg. coeff Choose variable Y, the first eqn is only one with neg. coeff No variable can be chosen, optimal value 2 is found

  33. The algorithm starting from a problem in bfs form repeat Choose a variable y with negative coefficient in the obj. func. Find the equation x = b + cy + ... where c<0 and -b/c is minimal Rewrite this equation with y the subject y = -b/c + 1/c x + ... Substitute -b/c + 1/c x + ... for y in all other eqns and obj. func. until no such variable y exists or no such equation exists if no such y exists optimum is found else there is no optimal solution The Simplex Algorithm

  34. The example Basic feasible solution form: circle Choose S3, replace using 2nd eq Optimal solution: box

  35. Content • Optimization – what is that? • The Simplex Algorithm – background • Simplex form • Basic feasible solved form / basic feasible solution • The algorithm • Initial basic feasible solved form The Simplex Algorithm

  36. Initial basic feasible solved form idea: • solve a different optimization problem this optimization problem should have an initial basic feasible solved form, which: • can be found trivially • has an optimal solution that leads to an initial basic feasible solved form of the original problem The Simplex Algorithm

  37. Initial basic feasible solved form add artificial variables and minimize on them: The Simplex Algorithm

  38. Initial basic feasible solved form to get basic feasible solved form:  solve this problem The Simplex Algorithm

  39. Initial basic feasible solved form possible outcomes: • (f > 0)  original problem unsatisfiable • (f = 0)  (zi...n parametric)  got a basic feasible solved form for original problem • (f = 0)  (zi...n parametric)  zi must occur in such an equation: The Simplex Algorithm

  40. Such an equation is no problem, because • if all a’j = 0 → equation is redundant • if one a’j≠ 0 → use according xj for pivoting z out of basic variables (this maintains basic feasible solved form since z = 0 +…)  all z become parametric The Simplex Algorithm

  41. An equivalent simplex form is: The example An optimization problem showing contours of the objective function

  42. The example Original simplex form equations With artificial vars in bfs form: Objective function: minimize

  43. The example Problem after minimization of objective function Removing the artificial variables, the original problem

  44. Simplex solver finding a basic feasible solution is exactly a constraint satisfaction problem  efficient constraint solver for linear inequalities The Simplex Algorithm

  45. Cycling Problem: • if for one of the basic variables is valid: Xi = 0 + … , a pivot could be performed which does not change the corresponding basic feasible solution  danger of pivoting back Solution: • use e.g. Bland’s anti-cycling rule (always select candidate with smallest index: x2 instead of x4) The Simplex Algorithm

  46. Summary We have seen that optimisations of linear real arithmetic constraints play an important role in many applications. The Simplex Method which was introduced here provides a very efficient algorithm to determine whether there exists an optimal solution to linear real arithmetic constraints and if there exists one, to compute it. The Simplex Algorithm

  47. Literature • books: George B. Dantzig, Mukund N. Thapa "Linear Programming I: Introduction" Springer Verlag Kim Marriott & Peter J. Stuckey "Programming with Constraints: An Introduction" MIT Press The Simplex Algorithm

  48. Literature • examples are taken from a presentation of Marriott & Stuckey and could be accessed via internet: http://www.cs.mu.oz.au/~pjs/book/course.html • this presentation in the net: http://www-lehre.inf.uos.de/~sbitzer/clp The Simplex Algorithm

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