Theory, development, and applicability of the surface water hydrologic model CASC2D

• Published in: Hydrological processes Vol. 16; no. 2; pp. 255 - 275
• Main Authors: Downer, Charles W., Ogden, Fred L., Martin, William D., Harmon, Russell S.
• Format: Journal Article Conference Proceeding
• Language: English
• Published: Chichester, UK John Wiley & Sons, Ltd 15.02.2002; Wiley
• Subjects: CASC2D; distributed; Earth sciences; Earth, ocean, space; erosion; Exact sciences and technology; Hydrology; Hydrology. Hydrogeology; modeling; rainfall; runoff; United States; rainfall; soil moisture; streams; runoff; rain water; North America; spatial distribution; surface water; drainage basins; hydrological modeling; erosion; prediction; two-dimensional models; hydrographs; theory
• ISSN: 0885-6087; 1099-1085
• DOI: 10.1002/hyp.338

Numerical tests indicate that Hortonian runoff mechanisms benefit from scaling effects that non‐Hortonian runoff mechanisms do not share. This potentially makes Hortonian watersheds more amenable to physically based modelling provided that the physically based model employed properly accounts for rainfall distribution and initial soil moisture conditions, to which these types of model are highly sensitive. The distributed Hortonian runoff model CASC2D has been developed and tested for the US Army over the past decade. The purpose of the model is to provide the Army with superior predictions of runoff and stream‐flow compared with the standard lumped parameter model HEC‐1. The model is also to be used to help minimize negative effects on the landscape caused by US armed forces training activities. Development of the CASC2D model is complete and the model has been tested and applied at several locations. These applications indicate that the model can realistically reproduce hydrographs when properly applied. These applications also indicate that there may be many situations where the model is inadequate. Because of this, the Army is pursuing development of a new model, GSSHA, that will provide improved numerical stability and incorporate additional stream‐flow‐producing mechanisms and improved hydraulics. Copyright © 2002 John Wiley & Sons, Ltd.