<p>Understanding pollutant–meteorology interactions is essential for environmental risk assessment. This study develops an entropy-based statistical framework to analyze static and temporal dependencies between urban air pollutants and meteorological variables across multiple Indian cities. Dependence is quantified using complementary linear and nonlinear measures, including Pearson correlation, mutual information, and relative conditional entropy. A key methodological contribution is a PCA-based composite indexing framework that integrates these heterogeneous metrics into a unified and interpretable correlation score. For each pollutant–meteorological pair within a city, PCA is used to extract a joint variability index, while spatial variability is assessed by aggregating correlations across cities. These indices are further combined to derive a comprehensive city-level correlation score that represents overall pollutant–meteorology coupling strength and enables classification of cities into distinct interaction regimes. Sensitivity analysis, performed by systematically excluding individual variable pairs, demonstrates the robustness of the framework, with no single pair exerting disproportionate influence. Temporal dependencies are examined using transfer entropy and time-delayed mutual information. Results indicate that relative humidity generally leads changes in pollutant concentrations, whereas ambient temperature tends to lag, highlighting contrasting causal influences. Mutual information peaks at zero lag and decays rapidly following an exponential form, indicating strong short-term interactions with limited persistence. Overall, the proposed framework provides a unified and interpretable approach for assessing complex pollutant–meteorology interactions across diverse locations and time.</p>

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Classifying urban regions by aggregated pollutant–weather correlation strength: a spatiotemporal study

  • Koyena Ghosh,
  • Suchismita Banerjee,
  • Urna Basu,
  • Banasri Basu

摘要

Understanding pollutant–meteorology interactions is essential for environmental risk assessment. This study develops an entropy-based statistical framework to analyze static and temporal dependencies between urban air pollutants and meteorological variables across multiple Indian cities. Dependence is quantified using complementary linear and nonlinear measures, including Pearson correlation, mutual information, and relative conditional entropy. A key methodological contribution is a PCA-based composite indexing framework that integrates these heterogeneous metrics into a unified and interpretable correlation score. For each pollutant–meteorological pair within a city, PCA is used to extract a joint variability index, while spatial variability is assessed by aggregating correlations across cities. These indices are further combined to derive a comprehensive city-level correlation score that represents overall pollutant–meteorology coupling strength and enables classification of cities into distinct interaction regimes. Sensitivity analysis, performed by systematically excluding individual variable pairs, demonstrates the robustness of the framework, with no single pair exerting disproportionate influence. Temporal dependencies are examined using transfer entropy and time-delayed mutual information. Results indicate that relative humidity generally leads changes in pollutant concentrations, whereas ambient temperature tends to lag, highlighting contrasting causal influences. Mutual information peaks at zero lag and decays rapidly following an exponential form, indicating strong short-term interactions with limited persistence. Overall, the proposed framework provides a unified and interpretable approach for assessing complex pollutant–meteorology interactions across diverse locations and time.