Editorial Type:
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Article Type:
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An All-Season Flash Flood Forecasting System for Real-Time Operations

Patrick Broxton The University of Arizona, Tucson, Arizona

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Peter A. Troch The University of Arizona, Tucson, Arizona

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Mike Schaffner National Weather Service, Salt Lake City, Utah

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Carl Unkrich USDA ARS Southwest Watershed Research Center, Tucson, Arizona

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David Goodrich USDA ARS Southwest Watershed Research Center, Tucson, Arizona

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Print Publication:
01 Mar 2014
DOI:
https://doi.org/10.1175/BAMS-D-12-00212.1
Page(s):
399–407
Restricted access

Flash floods can cause extensive damage to both life and property, especially because they are difficult to predict. Flash flood prediction requires high-resolution meteorological observations and predictions, as well as calibrated hydrological models, which should effectively simulate how a catchment filters rainfall inputs into streamflow. Furthermore, because of the requirement of both hydrological and meteorological components in flash flood forecasting systems, there must be extensive data handling capabilities built in to force the hydrological model with a variety of available hydrometeorological data and predictions, as well as to test the model with hydrological observations. The authors have developed a working prototype of such a system, called KINEROS/hsB-SM, after the hydrological models that are used: the Kinematic Erosion and Runoff (KINEROS) and hillslope-storage Boussinesq Soil Moisture (hsB-SM) models. KINEROS is an event-based overland flow and channel routing model that is designed to simulate flash floods in semiarid regions where infiltration excess overland flow dominates, while hsB-SM is a continuous subsurface flow model, whose model physics are applicable in humid regions where saturation excess overland flow is most important. In addition, KINEROS/hsB-SM includes an energy balance snowmelt model, which gives it the ability to simulate flash floods that involve rain on snow. There are also extensive algorithms to incorporate high-resolution hydrometeorological data, including stage III radar data (5 min, 1° by 1 km), to assist in the calibration of the models, and to run the model in real time. The model is currently being used in an experimental fashion at the National Weather Service Binghamton, New York, Weather Forecast Office.

CORRESPONDING AUTHOR: Patrick Broxton, The University of Arizona, Room 542, 1118 E 4th St., Tucson, AZ 85721, E-mail: broxtopd@email.arizona.edu

Supplements to this article are available online (10.1175/BAMS-D-12-00212.2 and 10.1175/BAMS-D-12-00212.3)

Flash floods can cause extensive damage to both life and property, especially because they are difficult to predict. Flash flood prediction requires high-resolution meteorological observations and predictions, as well as calibrated hydrological models, which should effectively simulate how a catchment filters rainfall inputs into streamflow. Furthermore, because of the requirement of both hydrological and meteorological components in flash flood forecasting systems, there must be extensive data handling capabilities built in to force the hydrological model with a variety of available hydrometeorological data and predictions, as well as to test the model with hydrological observations. The authors have developed a working prototype of such a system, called KINEROS/hsB-SM, after the hydrological models that are used: the Kinematic Erosion and Runoff (KINEROS) and hillslope-storage Boussinesq Soil Moisture (hsB-SM) models. KINEROS is an event-based overland flow and channel routing model that is designed to simulate flash floods in semiarid regions where infiltration excess overland flow dominates, while hsB-SM is a continuous subsurface flow model, whose model physics are applicable in humid regions where saturation excess overland flow is most important. In addition, KINEROS/hsB-SM includes an energy balance snowmelt model, which gives it the ability to simulate flash floods that involve rain on snow. There are also extensive algorithms to incorporate high-resolution hydrometeorological data, including stage III radar data (5 min, 1° by 1 km), to assist in the calibration of the models, and to run the model in real time. The model is currently being used in an experimental fashion at the National Weather Service Binghamton, New York, Weather Forecast Office.

CORRESPONDING AUTHOR: Patrick Broxton, The University of Arizona, Room 542, 1118 E 4th St., Tucson, AZ 85721, E-mail: broxtopd@email.arizona.edu

Supplements to this article are available online (10.1175/BAMS-D-12-00212.2 and 10.1175/BAMS-D-12-00212.3)

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