🤖 AI Summary
This study addresses the challenge in regional risk assessment posed by missing asset attributes, which introduces unquantifiable uncertainty in exposure information and compromises risk estimation accuracy. For the first time, it systematically decomposes and quantifies the uncertainty arising specifically from probabilistic exposure representation, isolating it from total risk uncertainty to elucidate its generation and propagation mechanisms within the assessment workflow. Methodologically, the research integrates machine learning with engineering rule sets to impute missing data and constructs a high-resolution bridge exposure inventory. Uncertainty propagation is then analyzed through a combination of analytical methods and Monte Carlo simulations. The approach significantly enhances the transparency of exposure modeling and improves the reliability of regional-scale risk assessments.
📝 Abstract
Exposure characterization in regional risk assessment aims to assign physical properties to the assets of interest so they can be associated with damage and loss functions. While this process has benefited from the growing availability of public infrastructure inventories, these datasets often lack the detailed attributes required for high-resolution risk assessment. Missing attributes are commonly inferred using predictive models or engineering-based rulesets. However, these imputations are inherently imperfect and can introduce bias and additional uncertainty in regional risk estimates. This study proposes a methodology to quantify the bias and uncertainty in regional risk assessment that arises from probabilistic exposure characterization. By integrating analytical and simulation-based approaches, the methodology decomposes the total uncertainty into contributions from incomplete exposure information as well as other sources, including hazard and damage characterization. This decomposition clarifies how bias and uncertainty associated with missing exposure information are generated and propagated through the risk assessment pipeline. The methodology is applied to both bridge-specific and regional risk assessments. A high-resolution bridge exposure inventory is developed using a data augmentation framework that combines publicly available information with machine learning and engineering-based imputation methods.