基于遗传算法的亚声速滑翔机机翼多目标优化

Q3 Computer Science
Ogedengbe I. I., Akintunde M. A., Dahunsi O. A., Bello E. I., B. P.
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引用次数: 0

摘要

无人驾驶飞行器(uav)的广泛采用可以追溯到其灵活性和对各种操作条件和应用的广泛适应性,相对较低的建造和维护成本以及环境友好性,因为它们可以很容易地配置为电力。电力的使用也有利于其低噪音应用,如监视。与监视相关的一个主要问题,正如本研究所述,是航程和续航操作模式之间的妥协。范围模式涉及到能够覆盖更长的距离,而耐力模式涉及到在固定充电的情况下在大气中花费更长的时间。试图平衡这些参数的相互作用会产生多目标优化,其中目标有些冲突。这导致了一组帕累托解,这是一组设计参数(主要是攻角),满足航程和续航性能参数的共同要求。本研究首先考虑了使用传统设计方法的基线气动设计。然后使用实验设计技术来选择最有利的设计点。利用该模型构建遗传优化算法的输入框架,部署在MATLAB的全局优化工具箱中。研究结果表明,在平均升阻比为20的情况下,与中攻角(AOA)设置(7度)相关的大部分区域共同满足良好的航程和续航力性能。这一结果意味着,在需要高AOA的监视中,低速阻力在中等设置下会大大减少,尽管在其他结构和空气动力学设置下(即长径比为13和锥度比为0.6)会稳定下来。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multi-objective Optimization of Subsonic Glider Wing Using Genetic Algorithm
The widespread adoption of Unmanned Aerial Vehicles (UAVs) can be traced to its flexibility and wide adaptability to various operating conditions and applications, comparably low cost of construction and maintenance and environmental friendliness as they can be easily configured for electric power. The use of electric power also favours its low noise applications such as surveillance. A major issue associated with surveillance, as addressed in this study is the compromise between Range and Endurance operation modes. The Range mode relates to being able to cover longer distances while the Endurance mode relates to spending longer times in the atmosphere for a fixed charge. Trying to balance the interplay of these parameters gave rise to a multi-objective optimization where the objectives are somewhat conflicting. This resulted in a set of Pareto solutions which are a set of design parameters (primarily angle of attack) that satisfy the joint requirements of the performance parameters of Range and Endurance. This study first considered a baseline aerodynamic design using traditional design methods. Design of Experiment techniques were then used to select the most favourable design points. This model was then used to build an input framework for Genetic Optimization algorithm deployed in the Global Optimization Toolbox of MATLAB. The result of this research shows that most of the region associated with medium angle of attack (AOA) setting (7 degrees) jointly satisfies good Range and Endurance performances with an average lift-to-drag ratio of 20 in the flight configuration considered. The implication of this result is that low velocity drag encountered in surveillance that requires a high AOA is largely reduced with the medium setting, albeit stabilized with other structural and aerodynamic settings, namely an aspect ratio of 13 and a taper ratio of 0.6.
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来源期刊
International Journal of Intelligent Systems and Applications in Engineering
International Journal of Intelligent Systems and Applications in Engineering Computer Science-Computer Graphics and Computer-Aided Design
CiteScore
1.30
自引率
0.00%
发文量
18
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