The increase in frequency and intensity of extreme precipitation events caused by the changing climate (e.g., cloudbursts, rainstorms, heavy rainfall, hail, heavy snow), combined with the high population density and concentration of assets, makes urban areas particularly vulnerable to pluvial flooding. Hence, assessing their vulnerability under current and future climate scenarios is of paramount importance. Detailed hydrologic-hydraulic numerical modeling is resource intensive and therefore scarcely suitable for performing consistent hazard assessments across large urban settlements. Given the steadily increasing availability of LiDAR (Light Detection And Ranging) high-resolution DEMs (Digital Elevation Models), several studies highlighted the potential of fast-processing DEM-based methods, such as the Hierarchical Filling-&-Spilling or Puddle-to-Puddle Dynamic Filling-&-Spilling Algorithms (abbreviated herein as HFSAs). We develop a fast-processing HFSA, named Safer_RAIN, that enables mapping of pluvial flooding in large urban areas by accounting for spatially distributed rainfall input and infiltration processes through a pixel-based Green-Ampt model. We present the first applications of the algorithm to two case studies in Northern Italy. Safer_RAIN output is compared against ground evidence and detailed output from a two-dimensional (2D) hydrologic and hydraulic numerical model (overall index of agreement between Safer_RAIN and 2D benchmark model: sensitivity and specificity up to 71% and 99%, respectively), highlighting potential and limitations of the proposed algorithm for identifying pluvial flood-hazard hotspots across large urban environments.
Abstract. Our study develops and tests a geostatistical technique for
locally enhancing macro-scale rainfall–runoff simulations on the basis of
observed streamflow data that were not used in calibration. We consider Tyrol
(Austria and Italy) and two different types of daily streamflow data:
macro-scale rainfall–runoff simulations at 11 prediction nodes and
observations at 46 gauged catchments. The technique consists of three main
steps: (1) period-of-record flow–duration curves (FDCs) are geostatistically
predicted at target ungauged basins, for which macro-scale model runs are
available; (2) residuals between geostatistically predicted FDCs and FDCs
constructed from simulated streamflow series are computed; (3) the
relationship between duration and residuals is used for enhancing simulated
time series at target basins. We apply the technique in cross-validation to
11 gauged catchments, for which simulated and observed streamflow series are
available over the period 1980–2010. Our results show that (1) the procedure
can significantly enhance macro-scale simulations (regional LNSE increases
from nearly zero to ≈0.7) and (2) improvements are significant for
low gauging network densities (i.e. 1 gauge per 2000 km2).
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