Exploration of Urban Subsystem Coupling Coordination Based on Resilience in Luohe City

Authors

  • Wang Xinyu Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development
  • Shi Zhen Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development
  • László Kollányi Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development
  • Yang Yang Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development
  • Liu Manshu Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development
  • Zhang Xiaoyan ELTE Eötvös Loránd University, Faculty of Science/Doctoral School of Earth Sciences

DOI:

https://doi.org/10.36249/4d.67.3700

Keywords:

Urban Resilience, Society-Economy-Ecology, Coupling Coordination Degree, ECO Model, Systems Theory

Abstract

With urbanization, the uncertainties faced by urban areas continue to increase, and in response, China's urban planning is transitioning from a focus on quantity to quality. Promoting system coupling and coordination helps to make urban areas more resilient to risk. This paper uses data from Luohe City (China) in 2022 as an example to calculate the inter-system coupling coordination degree (CCD), find the factors that obstruct resilience construction, and further explore the spatial heterogeneity of the obstacle factors. The synthetic evaluation model, coupling evaluation model, and obstacle diagnosis model are used to evaluate and analyze each subsystem. The results are as follows: According to the synthetic evaluation, the mean urban development value is 0.48, with high-value regions clustered in the Southeastern built-up zone. Mean value of urban coupling coordination is 0.66, the coordination level is 7 (Moderate Coordination). Urban development degree is positively correlated with CCD. Globally, the economy is the main factor obstructing resilient growth, but the core obstacle areas of the ecosystem are larger and have a wider impact. This study contributes to understanding the internal action of urban systems and provides data for balance development and urban resilience enhancement.

 

Author Biographies

  • Wang Xinyu, Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development

    PhD student
    e-mail: sdwangxinyuxw@126.com

  • Shi Zhen, Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development

    PhD student
    e-mail: Shi.Zhen@PhD.uni-mate.hu

  • László Kollányi, Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development

    associate professor, CSc
    e-mail: kollanyi.laszlo@uni-mate.hu

  • Yang Yang, Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development

    PhD student
    e-mail: Yang.Yang@phd.uni-mate.hu

  • Liu Manshu, Hungarian University of Agriculture and Life Sciences, Institute of Landscape Architecture, Urban Planning and Garden Art, Budapest, Department of Landscape Planning and Regional Development

    PhD student
    e-mail: lms_1002@163.com

  • Zhang Xiaoyan, ELTE Eötvös Loránd University, Faculty of Science/Doctoral School of Earth Sciences

    PhD student
    e-mail: zxy@student.elte.hu

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Published

2023-04-30

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Articles

How to Cite

Exploration of Urban Subsystem Coupling Coordination Based on Resilience in Luohe City. (2023). 4D Journal of Landscape Architecture and Garden Art, 67, 22-29. https://doi.org/10.36249/4d.67.3700

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