智能覆盖和经济高效的监测:基于公交车的城市空气质量移动传感

IF 7.1 1区 地球科学 Q1 ENVIRONMENTAL STUDIES
Meng Huang , Xinchi Li , Mingchuan Yang , Xi Kuai
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引用次数: 0

摘要

公交车移动传感技术是利用公交车的移动性收集高时空空气质量数据的一种经济有效的方法。然而,在从庞大的车队中选择最佳巴士子集以部署数量有限的传感器时,现有研究主要侧重于评估巴士对研究区域的覆盖范围,而忽略了特定地点连续覆盖之间的时间差。值得注意的是,污染物浓度随着时间的推移会出现平滑的变化,因此在很短的时间间隔内收集的数据是多余的。因此,本研究首先确定了评估不同地点空气质量监测重要性的五个关键标准。然后,提出了两个同时考虑研究区域时空覆盖范围和传感数据之间时间差的总线选择模型。具体来说,最大时空覆盖公交车选择模型(MaxCoverage)在保证连续传感器测量之间时间间隔的前提下,最大化整体时空覆盖范围;最小车队规模模型(MiniSize)则根据指定的监测时间间隔和计数要求,选择最少数量的公交车。使用来自中国深圳的真实公交车轨迹数据集进行的实验验证证明了所提模型的有效性。结果表明,MaxCoverage_TC1 模型的时间间隔比基准模型长 2.7 倍,MiniSize_TC1 模型的平均时间间隔长 1.4 倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Intelligent coverage and cost-effective monitoring: Bus-based mobile sensing for city air quality

Intelligent coverage and cost-effective monitoring: Bus-based mobile sensing for city air quality

Bus-based mobile sensing has emerged as a cost-effective approach for collecting high spatio-temporal air quality data by leveraging the mobility of buses. However, when selecting an optimal subset of buses from a large fleet for deploying a limited number of sensors, existing studies have primarily focused on assessing the coverage of the study area by buses, disregarding the temporal gap between consecutive coverage at specific locations. It is worth noting that pollutant concentrations exhibit smooth variations over time, rendering data collected at very short intervals redundant. Therefore, this study first identified five key criteria for evaluating the air quality monitoring importance in various locations. Then two bus selection models that consider both the spatiotemporal coverage of the study area and the temporal gap between sensing data are proposed. Specifically, the maximal spatio-temporal coverage bus selection model (MaxCoverage) maximizes overall spatio-temporal coverage with a guaranteed time interval between consecutive sensor measurements, and the minimal fleet size model (MiniSize) selects the minimum number of buses based on based on specified requirements for monitoring time interval and counts. Experimental validation using a real-world bus trajectory dataset from Shenzhen, China demonstrates the effectiveness of the proposed models. The results show that the MaxCoverage_TC1 model has time intervals 2.7 timeslots longer than the baseline, and the MiniSize_TC1 model has an average time interval that is 1.4 timeslots longer.

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来源期刊
CiteScore
13.30
自引率
7.40%
发文量
111
审稿时长
32 days
期刊介绍: Computers, Environment and Urban Systemsis an interdisciplinary journal publishing cutting-edge and innovative computer-based research on environmental and urban systems, that privileges the geospatial perspective. The journal welcomes original high quality scholarship of a theoretical, applied or technological nature, and provides a stimulating presentation of perspectives, research developments, overviews of important new technologies and uses of major computational, information-based, and visualization innovations. Applied and theoretical contributions demonstrate the scope of computer-based analysis fostering a better understanding of environmental and urban systems, their spatial scope and their dynamics.
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