Developed NSGA-II to Solve Multi Objective Optimization Models in WSNs

2018 International Conference on Advanced Science and Engineering (ICOASE) Pub Date : 2018-10-01 DOI:10.1109/ICOASE.2018.8548860

S. T. Hasson, Hayder Ayad Khudhair

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引用次数: 2

Abstract

"Wireless sensor networks (WSNs) are spatially distributed at diverse locations to monitor different physical or environmental conditions". Subject to the sensing part duty, sensors can transmit their data through the network to other nodes or to the base station. The growth of WSN applications was motivated to assist the awkward activities in military, industrial and healthcare applications. Sensors size and cost restrictions add many constraints on its performance such as energy, computational speed, "communications bandwidth" and memory. Most of the real-world engineering optimization problems represent multi-Objective problems. Objectives are often conflicting. Multi-objective optimization (MOO) is the optimization of conflicting objectives. Their solutions are set of answers that describe the best tradeoff between conflicting objectives. In this paper, a developed non-dominated sorting genetic algorithm (NSGA-II) will be proposed to address certain WSN issues. It aims to control the overlapping level between nodes via unit desk graph connectivity model. A suggested Multi-objective optimization model will also help in defining the best tradeoff between network coverage and connectivity as two competing objectives.

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开发NSGA-II求解无线传感器网络中的多目标优化模型

“无线传感器网络(wsn)在空间上分布在不同的位置，以监测不同的物理或环境条件”。在传感部分的职责下，传感器可以通过网络将其数据传输到其他节点或基站。WSN应用的增长是为了帮助军事、工业和医疗保健应用中的尴尬活动。传感器的尺寸和成本限制给其性能增加了许多限制，如能量、计算速度、“通信带宽”和内存。现实世界中大多数工程优化问题都是多目标问题。目标往往是相互冲突的。多目标优化(MOO)是对相互冲突的目标进行优化。他们的解决方案是一组描述冲突目标之间最佳权衡的答案。本文将提出一种改进的非支配排序遗传算法(NSGA-II)来解决某些无线传感器网络问题。它的目的是通过单元桌面图连接模型来控制节点之间的重叠程度。一个建议的多目标优化模型也将有助于定义网络覆盖和连接之间的最佳权衡作为两个相互竞争的目标。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 International Conference on Advanced Science and Engineering (ICOASE)

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