用于描述终端空域拥堵动态演变的优化 ST-Moran's I 模型

IF 2 4区工程技术 Q2 ENGINEERING, CIVIL

Journal of Advanced Transportation Pub Date : 2024-03-06 DOI:10.1155/2024/7151746

Honghao Chen, Xinping Zhu, Yajun Zou, Zhongkun Li, Tianxiong Zhang

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引用次数: 0

摘要

本研究旨在揭示终端空域拥堵的时空演变规律，深入分析拥堵问题，从而有效利用空域资源，制定有针对性的管制策略，提高空域运行的安全性和效率。起初，将航段流速转换为等效速度可作为运行状态的量化基准。随后，通过对空间权重矩阵、标准状态参数和时间维度的改进，开发出专门针对终端空域的增强版 ST-Moran's I 指数模型。研究利用成都终端空域的实际运行数据对该模型进行了验证，结果表明该模型具有显著的先进性。与传统模型相比，所提出的模型在空间和时间维度上分别提高了 62.5% 和 43.61% 的拥堵识别率。终端空域内的拥堵主要发生在离港-爬升段和进港-离港段的交汇处，表现出明显的时空迁移行为。所提出的模型准确地描述了航段拥堵的时空特征，为制定有针对性的拥堵管理策略提供了支持。

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Optimized ST-Moran’s I Model for Characterizing the Dynamic Evolution of Terminal Airspace Congestion

This study aims to unveil the spatiotemporal evolution of congestion within terminal airspace, offering an in-depth analysis of congestion concerns to effectively utilize airspace resources and devise targeted control strategies, thereby enhancing airspace operation safety and efficiency. Initially, converting segment flow rates into equivalent speeds serves as a quantitative benchmark for operational status. Subsequently, an enhanced version of the ST-Moran’s I index model, specifically tailored to terminal airspace, is developed by incorporating improvements across spatial weight matrices, standard state parameters, and temporal dimensions. Validating this model with actual operational data from Chengdu’s terminal airspace, the research demonstrates significant advancements. Compared to conventional models, the proposed model enhances recognition rates for congestion in spatial and temporal dimensions by 62.5% and 43.61%, respectively. Congestion within terminal airspace predominantly occurs at the intersection of departure-climb and approach-departure segments, exhibiting evident spatiotemporal migration behavior. The proposed model accurately delineates the spatiotemporal characteristics of segment congestion, offering support for tailored congestion management strategies.

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来源期刊

Journal of Advanced Transportation 工程技术-工程：土木

CiteScore

5.00

自引率

8.70%

发文量

466

审稿时长

7.3 months

期刊介绍： The Journal of Advanced Transportation (JAT) is a fully peer reviewed international journal in transportation research areas related to public transit, road traffic, transport networks and air transport. It publishes theoretical and innovative papers on analysis, design, operations, optimization and planning of multi-modal transport networks, transit & traffic systems, transport technology and traffic safety. Urban rail and bus systems, Pedestrian studies, traffic flow theory and control, Intelligent Transport Systems (ITS) and automated and/or connected vehicles are some topics of interest. Highway engineering, railway engineering and logistics do not fall within the aims and scope of JAT.