基于偏相关分析的动态空间约简方法在船体优化中的应用

IF 1.3 4区 工程技术 Q3 ENGINEERING, CIVIL Journal of Ship Research Pub Date : 2020-08-01 DOI:10.5957/JOSR.04190019
Qiang Zheng, Haichao Chang, Zuyuan Liu, Baiwei Feng
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引用次数: 0

摘要

基于计算流体动力学(CFD)的船体优化设计是一个计算密集型的复杂工程问题。由于变量多、设计性能空间复杂、计算量大等原因,船体优化效率较低。为了提高船体优化的效率,本文提出了一种基于偏相关分析的动态空间约简方法。所提出的方法动态地使用船体形状优化数据来分析和缩小相关设计变量的取值范围,从而大大提高了优化效率。将该方法用于S60船体的兴波阻力优化,并通过比较验证了该方法的可行性。1.引言近年来,为了促进绿色船舶的快速发展,基于计算流体动力学(CFD)的船体优化方法被许多研究人员广泛使用,如Tahara等人(2011)、Peri和Diez(2013)、Kim和Yang(2010)、Yang和Huang(2016)、Chang等人(2012)和Feng等人(2009)。然而,船体优化设计是一个典型的复杂工程问题。它需要大量的数值模拟计算,设计性能空间复杂,导致优化效率低,难以获得全局最优解。常用的解决方案包括1)高效的优化算法,2)近似模型技术,以及3)高性能集群计算机。然而,这些方法在解决方案的效率和质量方面仍然不能满足工程应用的要求。为了解决工程优化问题中优化效率低、难以获得最优解的问题,许多学者对设计空间缩减技术进行了研究。Reungsinkonkarn和Apirukvorapiit(2014)将搜索空间约简(SSR)算法应用于粒子群优化(PSO)算法,消除了通过SSR无法找到最优解的区域,提高了算法的优化效率。Chen等人(2015)和Diez等人(20142015)使用Karhunen-Loeve展开法对船体进行评估,消除了影响较小的因素,以实现设计变量较少的空间缩减建模。对非线性降维方法的进一步扩展可以在D’Agostino等人(2017)和Serani等人(2019)中找到。Jeong等人(2005)将空间缩减技术应用于叶轮的气动形状优化,使用粗糙集理论和决策树提取翼型设计规则以改进每个目标。高等人(2009)和王等人(2014)利用偏相关分析结果,解决了飞机气动外形优化设计中优化效率低的问题,缩小了相关设计变量的取值范围,重构了优化设计空间。李等人(2013)使用聚类方法将设计空间划分为几个较小的聚类空间,聚类方法是一种基于近似模型的全局优化方法,从而实现了设计空间的缩减。Chu(2010)将粗糙集理论和聚类方法相结合,应用于散货船概念设计阶段,从而实现了设计空间的探索和缩小。冯等人(2015)将粗糙集理论和序列空间约简方法应用于典型船体的阻力优化,以实现设计空间的约简。吴等人(2016)采用偏相关分析方法,缩小KCS集装箱船变量的设计空间,提高优化效率。上述空间缩减方法大多需要在优化初期对原始设计空间进行采样和计算,然后通过数据挖掘获得缩减后的设计空间。这个过程增加了采样的计算成本,使得控制优化效率变得困难。
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Application of Dynamic Space Reduction Method Based on Partial Correlation Analysis in Hull Optimization
Hull optimization design based on computational fluid dynamics (CFD) is a highly computationally intensive complex engineering problem. Because of reasons such as many variables, spatially complex design performance, and huge computational workload, hull optimization efficiency is low. To improve the efficiency of hull optimization, a dynamic space reduction method based on a partial correlation analysis is proposed in this study. The proposed method dynamically uses hull-form optimization data to analyze and reduce the range of values for relevant design variables and, thus, considerably improves the optimization efficiency. This method is used to optimize the wave-making resistance of an S60 hull, and its feasibility is verified through comparison. 1. Introduction In recent years, to promote the rapid development of green ships, hull optimization methods based on computational fluid dynamics (CFD) have been widely used by many researchers, such as Tahara et al. (2011), Peri and Diez (2013), Kim and Yang (2010), Yang and Huang (2016), Chang et al. (2012), and Feng et al. (2009). However, hull optimization design is a typically complex engineering problem. It requires many numerical simulation calculations, and the design performance space is complex, which has resulted in low optimization efficiency and difficulty in obtaining a global optimal solution. Commonly used solutions include 1) efficient optimization algorithms, 2) approximate model techniques, and 3) high-performance cluster computers. However, these methods still cannot satisfy the engineering application requirements in terms of efficiency and quality of the solution. To solve the problem of low optimization efficiency and difficulty in obtaining an optimal solution in engineering optimization problems, many scholars have conducted research on design space reduction technology. Reungsinkonkarn and Apirukvorapinit (2014) applied the search space reduction (SSR) algorithm to the particle swarm optimization (PSO) algorithm, eliminating areas in which optimal solutions may not be found through SSR to improve the optimization efficiency of the algorithm. Chen et al. (2015) and Diez et al. (2014, 2015) used the Karhunen–Loeve expansion to evaluate the hull, eliminating the less influential factors to achieve space reduction modeling with fewer design variables. Further extensions to nonlinear dimensionality reduction methods can be found in D'Agostino et al. (2017) and Serani et al. (2019). Jeong et al. (2005) applied space reduction techniques to the aerodynamic shape optimization of the vane wheel, using the rough set theory and decision trees to extract aerofoil design rules to improve each target. Gao et al. (2009) and Wang et al. (2014) solved the problem of low optimization efficiency in the aerodynamic shape optimization design of an aircraft, by using analysis results of partial correlation, which reduced the range of values of relevant design variables to reconstruct the optimized design space. Li et al. (2013) divided the design space into several smaller cluster spaces using the clustering method, which is a global optimization method based on an approximation model, thus achieving design space reduction. Chu (2010) combined the rough set theory and the clustering method for application to the concept design stage of bulk carriers, thus realizing the exploration and reduction of design space. Feng et al. (2015) applied the rough set theory and the sequential space reduction method to the resistance optimization of typical ship hulls to achieve the reduction of design space. Wu et al. (2016) used partial correlation analysis to reduce the design space of variables of a KCS container ship to improve optimization efficiency. Most of the above space reduction methods need to sample and calculate the original design space in the early stage of optimization and then obtain the reduced design space through data mining. This process increases the computational cost of sampling, making it difficult to control optimization efficiency.
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来源期刊
Journal of Ship Research
Journal of Ship Research 工程技术-工程:海洋
CiteScore
2.80
自引率
0.00%
发文量
12
审稿时长
6 months
期刊介绍: Original and Timely technical papers addressing problems of shipyard techniques and production of merchant and naval ships appear in this quarterly publication. Since its inception, the Journal of Ship Production and Design (formerly the Journal of Ship Production) has been a forum for peer-reviewed, professionally edited papers from academic and industry sources. As such, it has influenced the worldwide development of ship production engineering as a fully qualified professional discipline. The expanded scope seeks papers in additional areas, specifically ship design, including design for production, plus other marine technology topics, such as ship operations, shipping economic, and safety. Each issue contains a well-rounded selection of technical papers relevant to marine professionals.
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