# Flood propagation modelling with the Local Inertia Approximation:   theoretical and numerical analysis of its physical limitations

**Authors:** Luca Cozzolino, Luigi Cimorelli, Renata Della Morte, Giovanni, Pugliano, Vincenzo Piscopo, Domenico Pianese

arXiv: 1904.12564 · 2019-09-17

## TL;DR

This paper critically analyzes the Local Inertia Approximation (LInA) for flood modeling, revealing its fundamental physical and numerical limitations, and argues that traditional shallow water equations are more reliable for practical applications.

## Contribution

The paper provides a comprehensive theoretical and numerical analysis of LInA, demonstrating its severe physical and computational limitations compared to classical models.

## Key findings

- LInA always develops shocks at wetting-drying fronts.
- Drying of wet beds is forbidden in LInA.
- LInA solutions often do not exist for realistic topographies.

## Abstract

Attention of the researchers has increased towards a simplification of the complete Shallow water Equations called the Local Inertia Approximation (LInA), which is obtained by neglecting the advection term in the momentum conservation equation. In the present paper it is demonstrated that a shock is always developed at moving wetting-drying frontiers, and this justifies the study of the Riemann problem on even and uneven beds. In particular, the general exact solution for the Riemann problem on horizontal frictionless bed is given, together with the exact solution of the non-breaking wave propagating on horizontal bed with friction, while some example solution is given for the Riemann problem on discontinuous bed. From this analysis, it follows that drying of the wet bed is forbidden in the LInA model, and that there are initial conditions for which the Riemann problem has no solution on smoothly varying bed. In addition, propagation of the flood on discontinuous sloping bed is impossible if the bed drops height have the same order of magnitude of the moving-frontier shock height. Finally, it is found that the conservation of the mechanical energy is violated. It is evident that all these findings pose a severe limit to the application of the model. The numerical analysis has proven that LInA numerical models may produce numerical solutions, which are unreliable because of mere algorithmic nature, also in the case that the LInA mathematical solutions do not exist. The applicability limits of the LInA model are discouragingly severe, even if the bed elevation varies continuously. More important, the non-existence of the LInA solution in the case of discontinuous topography and the non-existence of receding fronts radically question the viability of the LInA model in realistic cases. It is evident that classic SWE models should be preferred in the majority of the practical applications.

---
Source: https://tomesphere.com/paper/1904.12564