Solid-liquid dual channel data-driven method for Lagrangian fluid simulation

2021 International Conference on Communications, Computing, Cybersecurity, and Informatics (CCCI) Pub Date : 2021-10-15 DOI:10.1109/CCCI52664.2021.9583218

Feilong Du, X. Ban, Yalan Zhang, Z. Dong, H. Duan

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引用次数: 1

Abstract

To solve the problems of low accuracy in long time series prediction and low generality of network parameter model in the existing data-driven Lagrangian fluid simulation, a light neural network prediction model which is physics-based multi-layer shared perceptron was proposed. Each fluid particle is standardized by searching neighbor particles through the optimized parallel processing module. The neural network is used to predict the effect of each neighbor particle on the central particle. The solid-liquid two-state differentiated aggregation operation is used to predict the acceleration of each fluid particle. The experimental results show that, compared with the existing methods, the method proposed in this paper greatly improves the prediction accuracy with less time overhead, and at the same time maintains more fluid motion details. In addition, we can enables more accurate long-term fluid motion prediction. Compared with PointRNN, PointNet++ and other single-channel data-driven methods, we can better deal with the fluid-solid coupling problem, and has wider network versatility.

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拉格朗日流体模拟的固液双通道数据驱动方法

针对现有数据驱动拉格朗日流体模拟中存在的长时间序列预测精度低、网络参数模型通用性低等问题，提出了一种基于物理的多层共享感知器的轻神经网络预测模型。通过优化后的并行处理模块，通过搜索相邻的流体粒子，对每个流体粒子进行标准化处理。神经网络用于预测每个相邻粒子对中心粒子的影响。采用固液两态微分聚集运算来预测各流体粒子的加速度。实验结果表明，与现有方法相比，本文提出的方法以较少的时间开销大大提高了预测精度，同时保持了更多的流体运动细节。此外，我们可以实现更准确的长期流体运动预测。与PointRNN、PointNet++等单通道数据驱动方法相比，能更好地处理流固耦合问题，具有更广泛的网络通用性。

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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来源期刊

2021 International Conference on Communications, Computing, Cybersecurity, and Informatics (CCCI)

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