A Quasi-Monte Carlo Volume Integration and Chebyshev Picard Iteration Method for Time-Parallel Nonlinear Seakeeping Computations

The 9th Conference on Computational Methods in Marine Engineering (Marine 2021) Pub Date : 2022-01-31 DOI:10.2218/marine2021.6833

David F. H Larson, P. Sclavounos

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Abstract

. The design and analysis of vessels and wave energy converters requires an under-standing of the nonlinear loads and responses in stochastic waves. A novel mesh-free potential ﬂow methodology is introduced for simulating the response of a ﬂoating body with nonlinear Froude-Krylov and hydrostatic e ﬀ ects. The nonlinear ﬂuid forces are cast as volume integrals using Fluid Impulse Theory (FIT). These volume integrals are robustly evaluated using Quasi-Monte Carlo (QMC) integration over an implicit geometry without the need to discretize the hull or free surfaces. The resulting nonlinear equation of motion is solved with an impulse-adapted Chebyshev Picard iteration scheme (I-MCPI). By approximating the nonlinear momentum impulse with a Chebyshev series, the time derivative can be analytically computed, circumventing the numerical sensitivity of ﬁnite-di ﬀ erencing. The solution is shown to converge over short parallelized subintervals, and sequentially concatenated to form long time records.

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拟蒙特卡罗体积积分与切比雪夫皮卡德迭代法的时间并行非线性耐波性计算

．船舶和波浪能转换器的设计和分析需要了解随机波浪中的非线性载荷和响应。介绍了一种新的无网格势流方法，用于模拟具有非线性弗劳德-克雷洛夫效应和流体静力效应的浮体的响应。利用流体冲量理论(FIT)将非线性流体力转换为体积积分。这些体积积分使用准蒙特卡罗(QMC)积分在隐式几何上进行稳健评估，而无需离散船体或自由表面。用自适应脉冲切比雪夫-皮卡德迭代格式(I-MCPI)求解得到的非线性运动方程。通过用切比雪夫级数逼近非线性动量脉冲，可以解析计算时间导数，从而避免了有限差分的数值敏感性。该解决方案在短的并行子区间内收敛，并顺序连接以形成长时间记录。

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The 9th Conference on Computational Methods in Marine Engineering (Marine 2021)

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