噪音(视频)
计算
不稳定性
物理
流体力学
磁流体驱动
跟踪(心理语言学)
涡流
反问题
统计物理学
磁流体力学
计算机科学
算法
等离子体
人工智能
机械
数学
数学分析
图像(数学)
哲学
量子力学
语言学
出处
期刊:Physical review
[American Physical Society]
日期:2024-08-06
卷期号:110 (2)
被引量:2
标识
DOI:10.1103/physreve.110.025302
摘要
Reconstructing the past of observed fluids has been known as an ill-posed problem due to both numerical and physical challenges, especially when observations are distorted by inevitable noise, resolution limits, or unknown factors. When employing traditional differencing schemes to reconstruct the past, the computation often becomes highly unstable or diverges within a few backward time steps from the distorted and noisy observation. Although several techniques have been recently developed for inverse problems, such as adjoint solvers and supervised learning, they are also unrobust against errors in observation when there is time-reversed simulation. Here we present that by using physics-informed neural computing, robust time-reversed fluid simulation is possible. By seeking a solution that closely satisfies the given physics and observations while allowing for errors, it reconstructs the most probable past from noisy observations. Our work showcases time rewinding in extreme fluid scenarios such as shock, instability, blast, and magnetohydrodynamic vortex. Potentially, this can be applied to trace back the interstellar evolution and determining the origin of fusion plasma instabilities.
科研通智能强力驱动
Strongly Powered by AbleSci AI