神经流动图上的流体模拟

Yitong Deng, Hong-Xing Yu, Diyang Zhang, Jiajun Wu, Bo Zhu
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引用次数: 0

摘要

我们介绍了一种新的模拟方法——神经流图,它将隐式神经表示与基于流图理论的流体模拟结合起来,以实现最先进的非粘性流体现象的模拟。我们设计了一种新的混合神经场表示,空间稀疏神经场(SSNF),它融合了具有重叠,多分辨率和空间稀疏网格的金字塔的小型神经网络,以高精度紧凑地表示长期时空速度场。有了这个神经速度缓冲,我们以机械对称的方式计算长期的双向流图及其雅可比矩阵,从而大大提高了现有解决方案的精度。这些远程的双向流图可以实现高平流精度和低耗散,从而促进高保真的不可压缩流动模拟,以显示复杂的旋涡结构。我们在各种具有挑战性的模拟场景中证明了我们的神经流体模拟的有效性,包括跨越式涡流、碰撞涡流、涡流重连以及由移动障碍物和密度差异产生的涡流。我们的例子表明,在节能、视觉复杂性、对实验观察的依从性和保留详细的垂直结构方面,比现有方法的性能有所提高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fluid Simulation on Neural Flow Maps
We introduce Neural Flow Maps, a novel simulation method bridging the emerging paradigm of implicit neural representations with fluid simulation based on the theory of flow maps, to achieve state-of-the-art simulation of in-viscid fluid phenomena. We devise a novel hybrid neural field representation, Spatially Sparse Neural Fields (SSNF), which fuses small neural networks with a pyramid of overlapping, multi-resolution, and spatially sparse grids, to compactly represent long-term spatiotemporal velocity fields at high accuracy. With this neural velocity buffer in hand, we compute long-term, bidirectional flow maps and their Jacobians in a mechanistically symmetric manner, to facilitate drastic accuracy improvement over existing solutions. These long-range, bidirectional flow maps enable high advection accuracy with low dissipation, which in turn facilitates high-fidelity incompressible flow simulations that manifest intricate vortical structures. We demonstrate the efficacy of our neural fluid simulation in a variety of challenging simulation scenarios, including leapfrogging vortices, colliding vortices, vortex reconnections, as well as vortex generation from moving obstacles and density differences. Our examples show increased performance over existing methods in terms of energy conservation, visual complexity, adherence to experimental observations, and preservation of detailed vortical structures.
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