跨越模式和规模的公共交通:慕尼黑网络案例研究。

IF 2.2 Q2 MULTIDISCIPLINARY SCIENCES
PNAS nexus Pub Date : 2024-10-31 eCollection Date: 2024-11-01 DOI:10.1093/pnasnexus/pgae489
Jan Mölter, Joanna Ji, Benedikt Lienkamp, Qin Zhang, Ana T Moreno, Maximilian Schiffer, Rolf Moeckel, Christian Kuehn
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引用次数: 0

摘要

公共交通系统的使用是人类复杂行为的一个突出例子。考虑到许多城市地区人口的急剧增长,公共交通的建模、规划和管理是未来的一大挑战。我们希望设计出能够应对动态增长需求的可持续城市,这就需要建立交通网络模型,因为我们无法在建设额外的基础设施之前进行实际实验。然而,建模过程中存在一个基本挑战:我们必须了解哪些基本原则适用于交通网络的设计。在这项工作中,我们将比较三种在公共交通建模中理解人类行为的科学方法:基于代理的模型、基于集中优化的模型和基于最小物理学的模型。作为案例研究,我们将重点关注德国慕尼黑的交通网络。我们的研究表明,无论选择哪种模型,公共交通都会出现某些普遍的宏观突现特征。特别是,我们可以通过最低限度的基本假设,为单个乘客的车内时间以及其他几种分布求得一个共同而稳健的分布。然而,还有其他更微观的特征,这些特征在个体组织和集中组织之间存在差异,并且/或者无法通过最小化的非局部随机行走类型模型再现。最后,我们用观测到的公共交通数据交叉验证了我们的结果。总之,我们的研究结果为我们理解未来可持续发展城市中人类行为交通模型的基本假设提供了重要依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Public transport across models and scales: A case study of the Munich network.

The use of public transport systems is a striking example of complex human behavior. Modeling, planning, and managing public transport is a major future challenge considering the drastically accelerated population growth in many urban areas. The desire to design sustainable cities that can cope with a dynamically increasing demand requires models for transport networks since we are not able to perform real-life experiments before constructing additional infrastructure. Yet, there is a fundamental challenge in the modeling process: we have to understand which basic principles apply to the design of transit networks. In this work, we are going to compare three scientific methods to understand human behavior in public transport modeling: agent-based models, centralized optimization-based models, and minimal physics-based models. As a case study, we focus on the transport network in Munich, Germany. We show that there are certain universal macroscopic emergent features of public transport that arise regardless of the model chosen. In particular, we can obtain with minimal basic assumptions a common and robust distribution for the individual passenger in-vehicle time as well as for several other distributions. Yet, there are other more microscopic features that differ between the individual and centralized organization and/or that cannot be reproduced by a minimal nonlocal random-walk type model. Finally, we cross-validate our results with observed public transport data. In summary, our results provide a key understanding of the basic assumptions that have to underlie transport modeling for human behavior in future sustainable cities.

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