AbstractThis paper deals with the rounding-error analysis of the simplex method for solving linear-programming problems. We prove that in general any simplex-type algorithm is not well behaved, which means that the computed solution cannot be considered as an exact solution to a slightly perturbed problem. We also point out that simplex algorithms with well-behaved updating techniques (such as the Bartels-Golub algorithm) are numerically stable whenever proper tolerances are introduced into the optimality criteria. This means that the error in the computed solution is of a similar order to the sensitivity of the optimal solution to slight data perturbations
In this paper we present the theoretical foundation of forward error analysis of numerical algorithm...
The largest dense linear systems that are being solved today are of order $n = 10^7$. Single precis...
Currently, the simplex method and the interior point method are indisputably the most popular algori...
AbstractThis paper deals with the rounding-error analysis of the simplex method for solving linear-p...
AbstractStandard implementations of the Simplex method have been shown to be subject to computationa...
AbstractA modification of the revised simplex algorithm is considered where every step involves O(m2...
AbstractA technique is described for resolving degeneracy in the simplex method for linear programmi...
Many problems in computer science and applied mathematics require rounding a vector ? of fractional ...
We study singularly perturbed linear programs. These are parametric linear programs whose constraint...
A problem arising in integer linear programming is transforming a solution of a linear system to an...
In this paper we perform a round-off error analysis of descent methods for solving a liner systemAx=...
AbstractWe describe a new exact-arithmetic approach to linear programming when the number of variabl...
A problem arising in integer linear programming is transforming a solution of a linear system to an ...
Degeneracy has been the subject of much research in the field of mathematical programming, since it ...
AbstractThe stability of algorithms in numerical linear algebra is discussed. The concept of stabili...
In this paper we present the theoretical foundation of forward error analysis of numerical algorithm...
The largest dense linear systems that are being solved today are of order $n = 10^7$. Single precis...
Currently, the simplex method and the interior point method are indisputably the most popular algori...
AbstractThis paper deals with the rounding-error analysis of the simplex method for solving linear-p...
AbstractStandard implementations of the Simplex method have been shown to be subject to computationa...
AbstractA modification of the revised simplex algorithm is considered where every step involves O(m2...
AbstractA technique is described for resolving degeneracy in the simplex method for linear programmi...
Many problems in computer science and applied mathematics require rounding a vector ? of fractional ...
We study singularly perturbed linear programs. These are parametric linear programs whose constraint...
A problem arising in integer linear programming is transforming a solution of a linear system to an...
In this paper we perform a round-off error analysis of descent methods for solving a liner systemAx=...
AbstractWe describe a new exact-arithmetic approach to linear programming when the number of variabl...
A problem arising in integer linear programming is transforming a solution of a linear system to an ...
Degeneracy has been the subject of much research in the field of mathematical programming, since it ...
AbstractThe stability of algorithms in numerical linear algebra is discussed. The concept of stabili...
In this paper we present the theoretical foundation of forward error analysis of numerical algorithm...
The largest dense linear systems that are being solved today are of order $n = 10^7$. Single precis...
Currently, the simplex method and the interior point method are indisputably the most popular algori...