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- Title
Improved Dynamic System Response Curve Method for Real‐Time Flood Forecast Updating.
- Authors
Si, Wei; Gupta, Hoshin V.; Bao, Weimin; Jiang, Peng; Wang, Wenzhuo
- Abstract
The dynamic system response curve (DSRC) method has been shown to effectively use error feedback correction to obtain updated areal estimates of mean rainfall and thereby improve the accuracy of real‐time flood forecasts. In this study, we address two main shortcomings of the existing method. First, ridge estimation is used to deal with ill‐conditioning of the normal equation coefficient matrix when the method is applied to small basins, or when the length of updating rainfall series is short. Second, the effects of spatial heterogeneity of rainfall on rainfall error estimates are accounted for using a simple index. The improved performance of the method is demonstrated using both synthetic and real data studies. For smaller basins with relatively homogeneous spatial distributions of rainfall, the use of ridge regression provides more accurate and robust results. For larger‐scale basins with significant spatial heterogeneity of rainfall, spatial rainfall error updating provides significant improvements. Overall, combining the two strategies results in the best performance for all cases, with the effects of ridge estimation and spatially distributed updating complementing each other. Key Points: Performance of the DSRC method is made more robust by incorporating ridge estimation to address shortcomings of the least squares approachThe method is extended to account for spatial heterogeneity in the rainfall distributionsSuperiority and applicability of the improved method is demonstrated via synthetic and real‐data studies
- Subjects
FLOOD forecasting; DYNAMICAL systems; LEAST squares; TREND analysis; ERROR correction (Information theory); MULTICOLLINEARITY
- Publication
Water Resources Research, 2019, Vol 55, Issue 9, p7493
- ISSN
0043-1397
- Publication type
Article
- DOI
10.1029/2019WR025520