基于云模型和贝叶斯网络的Natech灾害城市承载力评价研究

doi:10.12005/orms.2025.0261

摘要/Abstract

摘要： 全球气候的急剧变化极易破坏暴露于自然灾害下的工业设备,进而引发次生工业安全事故,其和自然灾害的风险叠加正威胁着工业区域的可持续发展。本文基于灾害链理论,利用贝叶斯网络描述以自然灾害为触发事件所引起的工业安全事故的连锁反应,识别城市系统失效的关键节点;随后,提出一种基于云贝叶斯网络的城市承载力评价方法,从基础设施、人口和环境承载力3个角度构建含有12个因素的评价指标体系,利用贝叶斯网络和云模型确定评估指标的等级量值区间,结合变异系数法获取缺失数据的节点权重;最后,评估珠江三角洲地区20092020年的城市承载力。研究发现:(1)珠江三角洲的城市发展对人口承载力有较强的依赖性;(2)珠江三角洲固有的社会发展模式不能有效应对工业的快速增长;(3)珠江三角洲内部城市的承载力差距较大,存在着承载力与城市发展趋势相反的现象。

关键词: 云模型, 贝叶斯网络, 组合权重, 城市承载力

Abstract: The rapid changes in global climate have heightened the frequency and intensity of natural disasters, posing a significant threat to industrial equipment exposed to such events. This vulnerability can lead to secondary industrial accidents, known as natural hazard triggered technological accidents (Natech), whose occurrence is steadily increasing. Accurately assessing the urban carrying capacity of industrial cities is a fundamental challenge in exploring the inherent development of cities. This assessment aims to enhance urban carrying capacity while maintaining the city’s intrinsic advantages. Currently, existing assessment methods for Natech often overlook the dynamic flow of risks within the Natech disaster chain, resulting in a lack of clarity in understanding the interactive relationships between different disaster events. Furthermore, research on carrying capacity primarily focuses on equipment and building structures, with limited emphasis on the urban system’s carrying capacity. Additionally, methods for evaluating urban or regional carrying capacity lack a systematic approach, with shortcomings in imperfect calculations for assessing the relevance of evaluation indicators, subjective weightings, and challenges in accurately quantifying multiple indicators. In this context, improving the evaluation model for urban carrying capacity in industrial cities and exploring key factors hold significant theoretical importance and practical value for the economic development and promotion of high-quality industrial growth in these cities.
In response to the prevailing issues of subjectivity, data scarcity, and uncertainties in indicator correlations within current evaluation models, this paper proposes a cloud Bayesian network approach integrating the coefficient of variation method. Utilizing a cloud generator to generate cloud model data, the model calculates the relative weights of unsupported nodes and obtains a conditional probability table. By objectively discretizing the states of each input node into three categories based on existing data within the Bayesian network, this model overcomes the subjective reliance on expert opinions prevalent in most urban carrying capacity studies. Simultaneously, the transformation of the fuzzy description of region numbers into a cloud map with specific numerical values addresses the challenge of lacking data support for intermediate nodes in the Bayesian network, completing the qualitative-to-quantitative conversion. Furthermore, by utilizing the cloud feature values of input nodes and their relative weights, the cloud feature values for relative nodes can be determined, establishing relative quantitative relationships based on weights. Finally, we select the Pearl River Delta industrial base, as the sample region. Three key indicators and twelve four-level assessment indicators are chosen to establish an index system for urban carrying capacity in the industrial area. The analysis spans 2009 to 2020, evaluating both overall the urban carrying capacity and individual indicators. The results indicate that the urban carrying capacity in the Pearl River Delta is consistently lower than the overall situation in Guangdong province. Moreover, the urban development in the Pearl River Delta demonstrates a significant dependence on population carrying capacity. The inherent social development model in the region proves ineffective in coping with the rapid growth of industry, highlighting an urgent need for improvements in waste disposal practices under large-scale industrial production. Furthermore, substantial disparities in the urban carrying capacity within the Pearl River Delta are observed, revealing instances where carrying capacity contradicts urban development trends.

Key words: cloud model, Bayesian network, combination weight, urban carrying capacity

中图分类号:

F280

王秋寒, 浦徐进. 基于云模型和贝叶斯网络的Natech灾害城市承载力评价研究[J]. 运筹与管理, 2025, 34(8): 192-198.

WANG Qiuhan, PU Xujin. Evaluation of Urban Carrying Capacity in Natech Based on Cloud Bayesian Model[J]. Operations Research and Management Science, 2025, 34(8): 192-198.

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