PEMODELAN DERET WAKTU KONSENTRASI PM10 DI KOTA SURABAYA DAN HUBUNGANNYA DENGAN FAKTOR METEOROLOGI DENGAN METODE EXPONENTIAL SMOOTHING DAN MACHINE LEARNING
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Fakultas Teknik
Abstract
Air pollution remains a major environmental issue in urban areas, particularly in
Surabaya, where particulate matter with an aerodynamic diameter of less than 10
µm (PM₁₀) poses significant risks to human health and the environment. This study
aims to model the time series of PM₁₀ concentrations in Surabaya and to examine
their relationship with meteorological variables, including average temperature
(TAVG), relative humidity (RH), wind speed (FF_AVG), and rainfall (RR). Several
statistical and machine learning approaches were employed, namely Exponential
Smoothing, Multiple Linear Regression (MLR), Gradient Boosting Regression
(GBR), and Random Forest (RF). Model performance was evaluated using Root
Mean Square Error (RMSE), Mean Absolute Error (MAE), Mean Absolute
Percentage Error (MAPE), and the Nash–Sutcliffe Efficiency (NSE), followed by an
aggregation ranking analysis. The results show that Multiple Linear Regression
achieved the best overall performance, particularly on the Kebonsari-exclusion
dataset, with an RMSE of 18.01 µg/m³, MAE of 13.41 µg/m³, MAPE of 28.10%, and
an NSE of 0.034, indicating more stable and accurate predictions compared to the
other methods. Forecasting results using the MLR model across four dataset
variants—Wonorejo-imputation, Kebonsari-imputation, Wonorejo-exclusion, and
Kebonsari-exclusion—over a three-day horizon demonstrated consistent trends and
robust performance, regardless of whether missing data were handled through
imputation or exclusion. Furthermore, analysis of the relationship between PM₁₀
and meteorological factors revealed spatial variability in dominant predictors. At
SPKUA Wonorejo, average temperature (TAVG) was identified as the most
influential variable, showing a positive relationship with PM₁₀ concentrations. In
contrast, wind speed (FF_AVG) emerged as the dominant factor at SPKUA
Kebonsari, where higher wind speeds were associated with lower PM₁₀
concentrations. Overall, this study confirms the effectiveness of Multiple Linear
Regression for PM₁₀ forecasting and provides methodological insights to support
air quality management in Surabaya.
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Validasi dan Finalisasi Repositori File 25 Juni 2026_Kholif Basri
