Azza H. Amer scite author profile

This paper focuses on multi-objective large-scale non-linear programming (MOLSNLP) problems with block angular structure. We extend the technique for order preference by similarity ideal solution (TOPSIS) to solve them. Compromise (TOPSIS) control minimizes the measure of distance, provided that the closest solution should have the shortest distance from the positive ideal solution (PIS) as well as the longest distance from the negative ideal solution (NIS). As the measure of ''closeness'' L P -metric is used. Thus, we reduce a q-dimensional objective space to a two-dimensional space by a firstorder compromise procedure. The concept of a membership function of fuzzy set theory is used to represent the satisfaction level for both criteria. Moreover, we derive a single objective large-scale non-linear programming (LSNLP) problem using the max-min operator for the second-order compromise operation. Finally, a numerical illustrative example is given to clarify the main results developed in this paper.

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An interactive algorithm for decomposing the parametric space in fuzzy multiobjective dynamic programming problem

Abo-Sinna¹,

Amer²,

Sayed³

2006

Applied Mathematics and Computation

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Implementation of the - Constraint Method in Special Class of Multi-objective Fuzzy Bi-Level Nonlinear Problems

Amer

2017

Pak.j.stat.oper.res.

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Geometric programming problem is a powerful tool for solving some special type nonlinear programming problems. In the last few years we have seen a very rapid development on solving multiobjective geometric programming problem. A few mathematical programming methods namely fuzzy programming, goal programming and weighting methods have been applied in the recent past to find the compromise solution. In this paper, -constraint method has been applied in bi-level multiobjective geometric programming problem to find the Pareto optimal solution at each level. The equivalent mathematical programming problems are formulated to find their corresponding value of the objective function based on the duality theorem at eash level. Here, we have developed a new algorithm for fuzzy programming technique to solve bi-level multiobjective geometric programming problems to find an optimal compromise solution. Finally the solution procedure of the fuzzy technique is illustrated by a numerical example.

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Azza H. Amer

Extensions of TOPSIS for multi-objective large-scale nonlinear programming problems

A multi-level non-linear multi-objective decision-making under fuzziness

Extensions of TOPSIS for large scale multi-objective non-linear programming problems with block angular structure

An interactive algorithm for decomposing the parametric space in fuzzy multiobjective dynamic programming problem

Implementation of the - Constraint Method in Special Class of Multi-objective Fuzzy Bi-Level Nonlinear Problems

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