通过最小流量问题预测和修正人流量

Hamza Ennaji, Noureddine Igbida, Ghadir Jradi
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摘要

我们研究了人群运动数学预测-校正模型的一种新变体。预测阶段由传输方程处理,其中矢量场是通过 eikonal 方程 ∥∇φ∥=f 计算的,而正连续函数 f 与自发移动的速度有关。修正阶段由新版本的最小流量问题处理。这个模型非常灵活,可以考虑到不同类型的介质之间的相互作用,从瓦塞尔塞廷空间的梯度流到沙堆中的颗粒型动力学。此外,还可以使用不同的边界条件,例如非均质 Dirichlet(例如具有不同出口成本惩罚的出口)和 Neumann 边界条件(例如具有不同速率的入口)。我们将有限体积法用于传输方程,将 Chambolle-Pock 原始对偶算法用于 eikonal 方程和最小流量问题,并进行了数值模拟,以演示不同情况下的行为。
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Prediction-correction pedestrian flow by means of minimum flow problem

We study a new variant of mathematical prediction-correction model for crowd motion. The prediction phase is handled by a transport equation where the vector field is computed via an eikonal equation φ=f, with a positive continuous function f connected to the speed of the spontaneous travel. The correction phase is handled by a new version of the minimum flow problem. This model is flexible and can take into account different types of interactions between the agents, from gradient flow in Wassersetin space to granular type dynamics like in sandpile. Furthermore, different boundary conditions can be used, such as non-homogeneous Dirichlet (e.g. outings with different exit-cost penalty) and Neumann boundary conditions (e.g. entrances with different rates). Combining finite volume method for the transport equation and Chambolle–Pock’s primal dual algorithm for the eikonal equation and minimum flow problem, we present numerical simulations to demonstrate the behavior in different scenarios.

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