This paper proposes a deep cut version of the ellipsoid algorithm for solving a general class of continuous convex programming problems. In each step the algorithm does not require more computational effort to construct these deep cuts than its corresponding central cut version. Rules that prevent some of the numerical instabilities and theoretical drawbacks usually associated with the algorithm are also provided. Moreover, for a large class of convex programs a simple proof of its rate of convergence is given and the relation with previously known results is discussed. Finally some computational results of the deep and central cut version of the algorithm applied to a min-max stochastic queue location problem are reported.</p
The ellipsoid method is an algorithm that solves the (weak) feasibility and linear optimization prob...
Multiplicative programming problems are global optimisation problems known to be NP-hard. In this pa...
"September 1997."Includes bibliographical references (p. 28-29).by R.M. Freund and J.R. Vera
This paper proposes a deep cut version of the ellipsoid algorithm for solving a general class of con...
This paper proposes a deep cut version of the ellipsoid algorithm for solving a general class of con...
textabstractThis paper proposes a deep cut version of the ellipsoid algorithm for solving a general ...
This paper proposes a deep cut version of the ellipsoid algorithm for solving a general class of con...
http://deepblue.lib.umich.edu/bitstream/2027.42/4192/5/bam3305.0001.001.pdfhttp://deepblue.lib.umich...
Abstract. In this paper, a class of min-max continuous location prob-lems is discussed. After giving...
In this paper, we study Ellipsoid method and modified Ellipsoid method in order to find a point whic...
The goal of the current paper is to introduce the notion of certificates which verify the accuracy o...
Let D be a DAG and let X be any non-empty subset of D\u27s vertices. X is a convex set of D if D con...
summary:We consider general convex large-scale optimization problems in finite dimensions. Under usu...
In this paper we study linear optimization problems with a newly introduced concept of multi-dimensi...
This thesis deals with a class of Lagrangian relaxation based algorithms developed in the computer s...
The ellipsoid method is an algorithm that solves the (weak) feasibility and linear optimization prob...
Multiplicative programming problems are global optimisation problems known to be NP-hard. In this pa...
"September 1997."Includes bibliographical references (p. 28-29).by R.M. Freund and J.R. Vera
This paper proposes a deep cut version of the ellipsoid algorithm for solving a general class of con...
This paper proposes a deep cut version of the ellipsoid algorithm for solving a general class of con...
textabstractThis paper proposes a deep cut version of the ellipsoid algorithm for solving a general ...
This paper proposes a deep cut version of the ellipsoid algorithm for solving a general class of con...
http://deepblue.lib.umich.edu/bitstream/2027.42/4192/5/bam3305.0001.001.pdfhttp://deepblue.lib.umich...
Abstract. In this paper, a class of min-max continuous location prob-lems is discussed. After giving...
In this paper, we study Ellipsoid method and modified Ellipsoid method in order to find a point whic...
The goal of the current paper is to introduce the notion of certificates which verify the accuracy o...
Let D be a DAG and let X be any non-empty subset of D\u27s vertices. X is a convex set of D if D con...
summary:We consider general convex large-scale optimization problems in finite dimensions. Under usu...
In this paper we study linear optimization problems with a newly introduced concept of multi-dimensi...
This thesis deals with a class of Lagrangian relaxation based algorithms developed in the computer s...
The ellipsoid method is an algorithm that solves the (weak) feasibility and linear optimization prob...
Multiplicative programming problems are global optimisation problems known to be NP-hard. In this pa...
"September 1997."Includes bibliographical references (p. 28-29).by R.M. Freund and J.R. Vera