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Similarity in Catchment Response: 2. Moving Rainstorms
Author(s) -
Ogden Fred L.,
Richardson Jerry R.,
Julien Pierre Y.
Publication year - 1995
Publication title -
water resources research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.863
H-Index - 217
eISSN - 1944-7973
pISSN - 0043-1397
DOI - 10.1029/95wr00519
Subject(s) - surface runoff , storm , dimensionless quantity , runoff model , kinematic wave , similarity (geometry) , geology , plane (geometry) , hydrology (agriculture) , environmental science , watershed , runoff curve number , meteorology , mechanics , geometry , mathematics , geotechnical engineering , physics , computer science , ecology , artificial intelligence , machine learning , image (mathematics) , biology
The influence of storm motion on runoff is explored, with a focus on dimensionless hydrologic similarity parameters. One‐ and two‐dimensional physically based runoff models are subjected to moving rainstorms. A dimensionless storm speed parameter Ut e / L p , where U is the storm speed, t e is the runoff plane kinematic time to equilibrium, and L p is the length of the runoff plane, is identified as a similarity condition. Storm motion effects on the peak discharge are greatest when the storm is traversing a one‐dimensional runoff plane in the downslope direction at a dimensionless speed of Ut e / L p = 0.5. This conclusion holds for all values of the dimensionless storm sizes L s / L p where L s is the length of the storm in the direction of motion. Simulations with a two‐dimensional rainfall‐runoff model confirm the applicability of this similarity parameter on natural watershed topography. Results indicate that the detailed simulation of storm motion is necessary when the storm is moving near the velocity of maximum effect, which is considerably slower than typical storm velocities.