Abstract
Abstract. Disaster risk reduction and management (DRRM) not only requires a thorough understanding of hazards but also knowledge of how much built-up structures are exposed and vulnerable to a specific hazard. This study proposed a rapid earthquake exposure and vulnerability mapping methodology using the municipality of Porac, Pampanaga as a case study. To address the challenges and limitations of data access and availability in DRRM operations, this study utilized Light Detection and Ranging (LiDAR) data and machine learning (ML) algorithms to produce an exposure database and conduct vulnerability estimation in the study area. Buildings were delineated through image thresholding and classification of the normalized Digital Surface Model (nDSM) and an exposure database containing building attributes was created using Geographic Information System (GIS). ML algorithms such as Support Vector Machine (SVM), logistic regression, and Random Forest (RF) were then used to predict the model building type (MBT) of delineated buildings to estimate seismic vulnerability. Results showed that the SVM model yielded the lowest accuracy (53%) while logistic regression and RF models performed fairly (72% and 78% respectively) as indicated by their F-1 scores. To improve the accuracy of the exposure database and vulnerability estimation, this study recommends that the proposed building delineation process be further refined by experimenting with more appropriate thresholds or by conducting point cloud classification instead of pixel-based image classification. Moreover, ground truth MBT samples should be used as training data for MBT prediction. For future work, the methodology proposed in this study can be implemented when conducting earthquake damage assessments.
Highlights
Disaster risk reduction and management (DRRM) requires an understanding of risk, hazards, and vulnerability and their interrelations amongst each other
Exposure mapping was conducted in a Geographic Information System (GIS) environment while vulnerability estimation was done using WEKA 3.8.5, an opensource data mining and machine learning software
The normalized Digital Surface Model (nDSM) was filtered twice using masks generated through thresholding—firstly, of digital terrain model (DTM)-derived terrain ruggedness index (TRI) raster and secondly, of nDSM-derived height values
Summary
Disaster risk reduction and management (DRRM) requires an understanding of risk, hazards, and vulnerability and their interrelations amongst each other. DRRM-related mapping efforts will only be effective if sufficient and reliable information is available. It remains a challenge for concerned government agencies and organizations to collect this information. Apart from being time-consuming, the data collection phase of DRRM operations often entails large monetary costs and manpower requirements. Oftentimes, DRRM initiatives stop during data collection phase and do not carry on with the analysis of the data collected due to resource constraints; in some cases, data collection activities are terminated prematurely due to budget constraints (Torres et al, 2019)
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