Accurate and efficient prediction of extreme ship responses continues to be a challenging problem in ship hydrodynamics. Probabilistic frameworks in conjunction with computationally efficient numerical hydrodynamic tools have been developed that allow researchers and designers to better understand extremes. However, the ability of these hydrodynamic tools to represent the physics quantitatively during extreme events is limited. Previous research successfully implemented the critical wave groups (CWG) probabilistic method with computational fluid dynamics (CFD). Although the CWG method allows for less simulation time than a Monte Carlo approach, the large quantity of simulations required is cost prohibitive. The objective of the present paper is to reduce the computational cost of implementing CWG with CFD, through the construction of long short-term memory (LSTM) neural networks. After training the models with a limited quantity of simulations, the models can provide a larger quantity of predictions to calculate the probability. The new framework is demonstrated with a 2-D midship section of the Office of Naval Research Tumblehome (ONRT) hull in Sea State 7 and beam seas at zero speed. The new framework is able to produce predictions that are representative of a purely CFD-driven CWG framework, with two orders of magnitude of computational cost savings.
翻译:在船舶流体动力学方面,对极端船只反应作出准确而有效的预测仍然是船舶流体动力学的一个挑战性问题。在计算高效的数字流体动力学工具的同时,已经制定了概率框架,使研究人员和设计者能够更好地了解极端现象,然而,这些流体动力学工具在极端事件期间在数量上代表物理学的能力有限。以前的研究成功地应用了关键波组(CWG)与计算流体动态(CFD)的概率方法。虽然CWG方法允许模拟时间比蒙特卡洛方法少,但大量模拟是成本过高的。本文件的目的是通过建造长期短期内存(LSTM)神经网络,减少与CFD一起实施CWG的计算成本。在对模型进行数量有限的模拟后,模型可以提供数量更多的预测来计算概率。新的框架通过海军研究办公室7号和7号海面的船体体体的两维中部分来证明,需要大量模拟是成本高昂的。新框架的目标是通过建造长期内存(CFD)神经网络网络网络来降低计算CFD的计算成本水平。新框架可以对CFD级价格进行两次的计算。