Operations research: an introduction, 4th ed.
Operations research: an introduction, 4th ed.
Affine Geometric Method For Linear Programs
Journal of Scientific Computing
O(n3) noniterative heuristic algorithm for linear programs with error-free implementation
Applied Mathematics and Computation
Applied Mathematics and Computation
An improved intial basis for the simplex algorithm
Computers and Operations Research
| Hi-index | 0.48 |
The simplex algorithm requires artificial variables for solving linear programs, which lack primal feasibility at the origin point. We present a new general-purpose solution algorithm, called push-to-pull, which obviates the use of artificial variables. The algorithm consists of preliminaries for setting up the initialization followed by two main phases. The push phase develops a basic variable set (BVS) which may or may not be feasible. Unlike simplex and dual simplex, this approach starts with an incomplete BVS initially, and then variables are brought into the basis one by one. If the BVS is complete, but the optimality condition is not satisfied, then push phase pushes until this condition is satisfied, using the rules similar to the ordinary simplex. Since the proposed strategic solution process pushes towards an optimal solution, it may generate an infeasible BVS. The pull phase pulls the solution back to feasibility using pivoting rules similar to the dual simplex method. All phases use the usual Gauss pivoting row operation and it is shown to terminate successfully or indicates unboundedness or infeasibility of the problem. A computer implementation, which further reduces the size of simplex tableau to the dimensions of the original decision variables, is provided. This enhances considerably the storage space, and the computational complexity of the proposed solution algorithm. Illustrative numerical examples are also presented.