Comparative analysis of overland flow models using finite volume schemes

176

120

This paper presents the decoupled hydrological discretization (DHD) scheme for solving the shallow water equations in hydrological applications involving surface runoff in rural and urban basins. The name of the scheme is motivated by the fact that the three equations which form the two-dimensional shallow water system are discretized independently from each other and thus, the numerical scheme is decoupled in a mathematical sense. Its main advantages compared to other classic finite volume schemes for the shallow water equations are its simplicity to code and the lower computational cost per time step. The validation of the scheme is presented in five test cases involving overland flow and rainfall-runoff transformation over topographies of different complexity. The scheme is compared to the finite volume scheme of Roe (1986), to the simple inertia formulation, and to the diffusive wave model. The test cases show that the DHD scheme is able to compute subcritical and supercritical flows in rural and urban environments, and that in overland flow applications it gives similar results to the second-order scheme of Roe with a lower computational cost. The results obtained with the simple inertia and diffusive wave models are very similar to those obtained with the DHD scheme in rural basins in which the bed friction and topography dominate the flow hydrodynamics but they deteriorate in typical urban configurations in which the presence of supercritical flow conditions and small-scale patterns boost the relevance of the inertial terms in the momentum equations.

Section: Introductionmentioning

confidence: 99%

A simple and efficient unstructured finite volume scheme for solving the shallow water equations in overland flow applications

Cea

Castellet

2015

176

120

“…Except in some theoretical cases, it is not possible to derive analytical solutions for the 2-D SWEs, and therefore, numerical schemes have to be used in order to obtain a solution for these equations. In particular, on the basis of the authors' experience on these kind of simulations (Costabile & Macchione, 2015;Costabile et al, 2012Costabile et al, , 2013Costabile et al, , 2017Macchione, Costabile, Costanzo, & De Santis 2019;Macchione, Costabile, Costanzo, & De Lorenzo, 2019), the first-order shock-capturing scheme reported in Appendix A has been used here. It is important to observe that this numerical model used here is characterized by well-balanced properties.…”

Section: Numerical Issues and Computational Domainsmentioning

confidence: 99%

“…Moreover, the increasing availability of high-topographic detail offered by Light Detection and Ranging (LiDAR) surveys allows the use of fine meshes that, in turn, gives the opportunity for the resolution of small-scale flow patterns, increasing the relevance of inertial terms in the hydrodynamic simulation of the surface runoff (Cea & Bladé, 2015). Considering the added value that they can provide in terms of the physical representation of the overland flow phenomenon using high-resolution digital elevation model (DEM), the SWEs are increasingly recognized as the most suitable approach for the description of hydrodynamic-based surface runoff computations in rainfall-runoff simulations at the catchment scale (Bellos & Tsakiris, 2016;Bout & Jetten, 2018;Caviedes-Voullième et al, 2012;Cea & Bladé, 2015;Cea et al, 2010;Costabile et al, 2012Costabile et al, , 2013Fernández-Pato et al, 2016;Hou et al, 2018;Huang et al, 2015;Liang et al, 2015;Simons et al, 2014;Singh et al, 2015;Xia et al, 2017;Xia & Liang, 2018;Yeh et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Hydraulic Characterization of River Networks Based on Flow Patterns Simulated by 2‐D Shallow Water Modeling: Scaling Properties, Multifractal Interpretation, and Perspectives for Channel Heads Detection

Costabile

Costanzo

Bartolo

et al. 2019

This paper is focused on the contribution that the two‐dimensional Shallow Water Equations could provide in respect to the fields of research devoted to the river networks analysis. The novelty introduced in this work is represented, in particular, by the hydraulic characterization of the river drainage networks, starting from flow patterns simulated by the two‐dimensional Shallow Water Equations on high‐resolution digital elevation model (DEM) through the analysis of water depths flowing down the hillslopes, channelized in both the main river and in all the tributaries or stored in small depressions. The first finding of this research is the determination of scaling laws that describe the relations between the water depth threshold, used to identify the network cells, and a dimensionless area, related to the total area of the network cells themselves. The observed bimodal scaling behavior has been considered as representative of the flow patterns belonging to the channel networks (CN) and hillslope plus channel networks (HCN), the physical and geomorphological interpretation of which has been provided from a multifractal point of view. In particular, the analysis of the multifractal spectra highlights significant variations in the multifractal signatures, between the CN and the HCN structures, leading to the proposal of a novel criterion for channels heads detection that has provided encouraging predictions of field observations.

“…Traditionally, hydrological models or simplified hydrodynamic models [ Lighthill and Whitham , ; Govindaraju , ; Bates et al ., ] are usually used for overland flow simulations at a catchment scale. However, most of these simplified models are not capable of depicting the rapid catchment responses and the highly transient surface flow processes to accurately predict water depths and velocities the flood waves [e.g., Cea et al ., ; Costabile et al ., ]. Moreover, their reduced representation of physical complexity may lead to increased sensitivity to parameterization.…”

Section: Introductionmentioning

confidence: 99%

An efficient and stable hydrodynamic model with novel source term discretization schemes for overland flow and flood simulations

Xia

Liang

Ming

et al. 2017

153

Numerical models solving the full 2‐D shallow water equations (SWEs) have been increasingly used to simulate overland flows and better understand the transient flow dynamics of flash floods in a catchment. However, there still exist key challenges that have not yet been resolved for the development of fully dynamic overland flow models, related to (1) the difficulty of maintaining numerical stability and accuracy in the limit of disappearing water depth and (2) inaccurate estimation of velocities and discharges on slopes as a result of strong nonlinearity of friction terms. This paper aims to tackle these key research challenges and present a new numerical scheme for accurately and efficiently modeling large‐scale transient overland flows over complex terrains. The proposed scheme features a novel surface reconstruction method (SRM) to correctly compute slope source terms and maintain numerical stability at small water depth, and a new implicit discretization method to handle the highly nonlinear friction terms. The resulting shallow water overland flow model is first validated against analytical and experimental test cases and then applied to simulate a hypothetic rainfall event in the 42 km2 Haltwhistle Burn, UK.