非线性系统
供求关系
随机森林
空间分析
计算机科学
城市热岛
匹配(统计)
环境科学
自相关
空间不匹配
需求模式
时空格局
人工智能
极化(电化学)
空格(标点符号)
空间生态学
计量经济学
城市规划
空间变异性
机器学习
支持向量机
空间相关性
空间构型
自然地理学
气候变化
芯(光纤)
热的
作者
Yijun SHI,Yijun SHI,Yuhang Shi,Yuhang Shi,Xinyu Zhou,Wei Zhai,Junqing Tang,Shutian Zhou
出处
期刊:urban climate
[Elsevier BV]
日期:2026-01-26
卷期号:65: 102792-102792
标识
DOI:10.1016/j.uclim.2026.102792
摘要
Urban blue-green spaces (BGS) are critical for mitigating heat islands, yet the nonlinear dynamics between cooling supply and demand remain underexplored. This study establishes a spatial identification-mechanistic diagnosis framework to investigate these dynamics in Hangzhou from 2016 to 2022. First, spatially explicit Urban Cooling Demand (CEDL) and Supply (CESL) indices were constructed using a Geographically Weighted Random Forest (GWRF) approach to capture local parameter sensitivity. Local Spatial Autocorrelation (LISA) was then applied to pinpoint supply-demand mismatched zones. Subsequently, LightGBM, SHAP, and Partial Dependence Plots (PDP) were integrated to diagnose the nonlinear drivers specifically within these mismatched regions. Results reveal a spatial polarization: high cooling demand areas expanded outward in dense urban cores, while high supply regions contracted inward near ecological barriers. The mismatch analysis identified dominant Low Supply-High Demand (LS-HD) zones in the city center, primarily driven by the ‘Distance to Nearest BGS’ and ‘Building Shape Index,’ with PDP revealing a critical cooling attenuation threshold at 200–300 m. Conversely, High Supply-Low Demand (HS-LD) zones in the periphery were sustained by landscape connectivity but faced increasing erosion from suburban sprawl. These findings move beyond global linear assumptions, providing data-driven, spatially targeted strategies—such as micro-park insertion in core zones and connectivity preservation in fringes—to alleviate urban heat inequity. • A “spatial identification-mechanistic diagnosis” framework integrates Geographically Weighted Random Forest (GWRF) and interpretable machine learning. • Spatiotemporal polarization intensifies: cooling demand expands outward in urban cores while supply contracts inward near ecological barriers. • ‘Distance to Nearest BGS’ and ‘Building Shape Index’ are identified as the dominant drivers of heat accumulation in Low Supply-High Demand zones. • Partial Dependence Plots reveal a critical nonlinear threshold where cooling benefits diminish rapidly beyond 200–300 m from blue-green spaces.
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